System and method for merge assist using vehicular communication

ABSTRACT

A computer-implemented method for controlling a vehicle system of a host vehicle merging into a lane. The method includes determining an actual distance between the host vehicle and the one or more remote vehicles. The actual distance is a longitudinal distance between the host vehicle and the one or more remote vehicles. The method includes determining a safe distance for merging into the lane based on a relative position of the host vehicle to the one or more remote vehicles, a speed of the host vehicle, and a speed of the one or more remote vehicles. The safe distance is a second longitudinal distance between the host vehicle and the one or more remote vehicles. The method includes controlling the vehicle system of the host vehicle to assist a merge maneuver by the host vehicle according to the actual distance and the safe distance.

RELATED APPLICATIONS

This application is a continuation of U.S. Ser. No. 15/630,866 filed Jun. 22, 2017 and now published as U.S. Pub. No. US 2017/0369067. U.S. Ser. No. 15/630,866 is a continuation-in-part of U.S. Ser. No. 15/191,358 filed Jun. 23, 2016. U.S. Ser. No. 15/630,866 claims the benefit of U.S. Provisional Ser. No. 62/442,333 filed Jan. 4, 2017 and also claims the benefit of U.S. Provisional Ser. No. 62/442,190 filed Jan. 4, 2017. The above applications are expressly incorporated herein by reference.

BACKGROUND

Vehicle travel can be affected by many different variables such as, other vehicles, objects, obstructions, hazards, and environmental conditions (herein referred to as hazards). As an illustrative example, traffic congestion, lane closures, disabled vehicles, collisions, and/or debris on a road can cause significant delays for vehicle travel and can compromise road safety. A driver of a vehicle may be unaware of these different variables that affect vehicle travel. In some circumstances, a driver is unable to see a hazard beyond a certain surrounding of the vehicle. For example, the driver's vision may be diminished or completely obstructed by a large vehicle, traffic congestion, and/or weather conditions. The driver's vision may also be reduced due to road geometry such as curvatures.

Further, the driver is generally unaware of intimate knowledge about the dynamics of other vehicles on the road and the drivers of the other vehicles. For example, the driver may not know the speed or maneuver intentions of other vehicles on the road. Vehicle sensory systems (e.g., radar, camera) implemented in the vehicle can detect some hazards. However, these sensory systems have a limited detection range within an immediate surrounding of a vehicle. Thus, the driver does not have information about obstructions further ahead or behind, neither at a road level nor at a lane level, outside of the surrounding environment of the vehicle. Vehicle communication with other vehicles and infrastructures can address some of the hazards discussed above when the information communicated is synergistically applied to a vehicle or many vehicles.

BRIEF DESCRIPTION

According to one aspect, a computer-implemented method computer-implemented method for controlling a vehicle system of a host vehicle merging with one or more remote vehicles includes determining an intent to merge into a lane based on host vehicle data received from a sensor system of the host vehicle. The method includes receiving speed data transmitted from the one or more remote vehicles via a vehicular communication network. The one or more remote vehicles are located within the lane. The method includes receiving position data of the one or more remote vehicles from the sensor system of the host vehicle that monitors an area around the host vehicle. Upon determining the one or more remote vehicles are in the area around the host vehicle based on the position data, the method includes determining a safe distance for merging into the lane based on a relative position of the host vehicle to the one or more remote vehicles, a speed of the host vehicle, and a speed of the one or more remote vehicles. Further, the method includes controlling the vehicle system of the host vehicle according to an actual distance between the host vehicle and the one or more remote vehicles and the safe distance.

According to another aspect, a vehicle control system for controlling a vehicle system of a host vehicle merging into a lane having one or more remote vehicles includes a wireless transceiver. The wireless transceiver receives message packets transmitted from the one or more remote vehicles via one or more communication links using a vehicular communication network. Each message packet contains speed data of the one or more remote vehicles from which the message packet is transmitted. The system includes a sensor system to receive position data of the one or more remote vehicles. The sensor system monitors an area around the host vehicle. The system includes a processor operatively connected for computer communication to the wireless transceiver and the sensor system. The processor determines the one or more remote vehicles are in the area around the host vehicle based on the position data. The processor calculates a safe distance for merging into the lane based on a relative position of the host vehicle to the one or more remote vehicles, a speed of the host vehicle, and a speed of the one or more remote vehicles. The processor controls motion of the host vehicle according to an actual distance between the host vehicle and the one or more remote vehicles and the safe distance.

According to a further aspect, a non-transitory computer-readable storage medium including instructions that when executed by a processor, cause the processor to determine an intent to merge into a lane based on host vehicle data received from a sensor system of a host vehicle. The processor also receives speed data transmitted from one or more remote vehicles via a vehicular communication network. The one or more remote vehicles are located within the lane. The processor receives position data of the one or more remote vehicles from the sensor system of the host vehicle that monitors an area around the host vehicle and determines the one or more remote vehicles are in the area around the host vehicle based on the position data. The processor determines a safe distance for merging into the lane based on a relative position of the host vehicle to the one or more remote vehicles, a speed of the host vehicle, and a speed of the one or more remote vehicles. Further, the processor control a vehicle system of the host vehicle according to an actual distance between the host vehicle and the one or more remote vehicles and the safe distance.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a schematic view of an exemplary traffic scenario according to one embodiment;

FIG. 1B is a schematic view of vehicles in the second lane 104 b of FIG. 1A according to an exemplary embodiment;

FIG. 2 is a schematic view of a vehicle communication network according to an exemplary embodiment;

FIG. 3 is a block diagram of a vehicle control system of a vehicle according to an exemplary embodiment;

FIG. 4 is a schematic view of exemplary vehicle systems that can be associated with the vehicle of FIG. 3 according to one embodiment;

FIG. 5 is a schematic view of an exemplary interior of the vehicle according to an exemplary embodiment;

FIG. 6 is a schematic view of a C-ACC control model for controlling a vehicle control system according to an exemplary embodiment;

FIG. 7 is a block diagram of an exemplary control system of the C-ACC control system according to an exemplary embodiment;

FIG. 8 is a process flow diagram of a method for controlling a vehicle control system according to an exemplary embodiment;

FIG. 9 is a process flow diagram of a method for calculating an acceleration control rate for a host vehicle according to an exemplary embodiment;

FIG. 10 is a process flow diagram of a method for selecting a leading vehicle according to an exemplary embodiment;

FIG. 11 is a process flow diagram of a method for monitoring a communication link for packet loss between a host vehicle and a remote vehicle according to an exemplary embodiment;

FIG. 12 is a schematic view of an exemplary traffic scenario for hazard detection according to one embodiment;

FIG. 13 is a process flow diagram of a method for detecting a hazard and controlling a vehicle control system according to an exemplary embodiment;

FIG. 14A is a process flow diagram of a method for classifying a remote vehicle according to an exemplary embodiment;

FIG. 14B is a illustrative example used to describe classifying a remote vehicle ahead of the host vehicle of FIG. 14A according to an exemplary embodiment;

FIG. 14C is a process flow diagram of a method for predicting lateral offset for classifying a remote vehicle according an exemplary embodiment;

FIG. 15 is a process flow diagram of a method for detecting traffic flow hazards based on vehicle communication and controlling a vehicle control system according to an exemplary embodiment;

FIG. 16 is a process flow diagram of a method for detecting a hazard based on remote vehicle lane change and controlling a vehicle control system according to an exemplary embodiment;

FIG. 17 is a schematic view of a traffic scenario for detecting a hazard according to an exemplary embodiment;

FIG. 18 is a schematic view of an exemplary traffic scenario for merge assist according to one embodiment;

FIG. 19 is a process flow diagram for providing merge assist using a vehicle communication network according to an exemplary embodiment;

FIG. 20 is a process flow diagram for providing merge assist with speed guidance using a vehicle communication network according to an exemplary embodiment;

FIG. 21 is a process flow diagram for providing merge assist with position guidance using a vehicle communication network according to an exemplary embodiment.

FIG. 22A is an illustrative embodiment of a scenario where no radar objects are detected, according to an exemplary embodiment;

FIG. 22B is an illustrative embodiment of a side by side merge scenario, according to an exemplary embodiment;

FIG. 22C is an illustrative embodiment of the host vehicle at tail merge scenario, according to an exemplary embodiment;

FIG. 22D is an illustrative embodiment of the host vehicle at lead merge scenario, according to an exemplary embodiment;

FIG. 22E is an illustrative embodiment of the host vehicle in between scenario according to a front safe distance, according to an exemplary embodiment; and

FIG. 22F is an illustrative embodiment of the host vehicle in between scenario according to a rear safe distance, according to an exemplary embodiment.

DETAILED DESCRIPTION

The following includes definitions of selected terms employed herein. The definitions include various examples and/or forms of components that fall within the scope of a term and that can be used for implementation. The examples are not intended to be limiting. Further, the components discussed herein, can be combined, omitted or organized with other components or into organized into different architectures.

“Bus,” as used herein, refers to an interconnected architecture that is operably connected to other computer components inside a computer or between computers. The bus can transfer data between the computer components. The bus can be a memory bus, a memory processor, a peripheral bus, an external bus, a crossbar switch, and/or a local bus, among others. The bus can also be a vehicle bus that interconnects components inside a vehicle using protocols such as Media Oriented Systems Transport (MOST), Processor Area network (CAN), Local Interconnect network (LIN), among others.

“Component”, as used herein, refers to a computer-related entity (e.g., hardware, firmware, instructions in execution, combinations thereof). Computer components may include, for example, a process running on a processor, a processor, an object, an executable, a thread of execution, and a computer. A computer component(s) can reside within a process and/or thread. A computer component can be localized on one computer and/or can be distributed between multiple computers.

“Computer communication”, as used herein, refers to a communication between two or more computing devices (e.g., computer, personal digital assistant, cellular telephone, network device) and can be, for example, a network transfer, a file transfer, an applet transfer, an email, a hypertext transfer protocol (HTTP) transfer, and so on. A computer communication can occur across, for example, a wireless system (e.g., IEEE 802.11), an Ethernet system (e.g., IEEE 802.3), a token ring system (e.g., IEEE 802.5), a local area network (LAN), a wide area network (WAN), a point-to-point system, a circuit switching system, a packet switching system, among others.

“Computer-readable medium,” as used herein, refers to a non-transitory medium that stores instructions and/or data. A computer-readable medium can take forms, including, but not limited to, non-volatile media, and volatile media. Non-volatile media can include, for example, optical disks, magnetic disks, and so on. Volatile media can include, for example, semiconductor memories, dynamic memory, and so on. Common forms of a computer-readable medium can include, but are not limited to, a floppy disk, a flexible disk, a hard disk, a magnetic tape, other magnetic medium, an ASIC, a CD, other optical medium, a RAM, a ROM, a memory chip or card, a memory stick, and other media from which a computer, a processor or other electronic device can read.

“Database,” as used herein, is used to refer to a table. In other examples, “database” can be used to refer to a set of tables. In still other examples, “database” can refer to a set of data stores and methods for accessing and/or manipulating those data stores. A database can be stored, for example, at a disk and/or a memory.

“Disk,” as used herein can be, for example, a magnetic disk drive, a solid-state disk drive, a floppy disk drive, a tape drive, a Zip drive, a flash memory card, and/or a memory stick. Furthermore, the disk can be a CD-ROM (compact disk ROM), a CD recordable drive (CD-R drive), a CD rewritable drive (CD-RW drive), and/or a digital video ROM drive (DVD ROM). The disk can store an operating system that controls or allocates resources of a computing device.

“Input/output device” (I/O device) as used herein can include devices for receiving input and/or devices for outputting data. The input and/or output can be for controlling different vehicle features which include various vehicle components, systems, and subsystems. Specifically, the term “input device” includes, but it not limited to: keyboard, microphones, pointing and selection devices, cameras, imaging devices, video cards, displays, push buttons, rotary knobs, and the like. The term “input device” additionally includes graphical input controls that take place within a user interface which can be displayed by various types of mechanisms such as software and hardware based controls, interfaces, touch screens, touch pads or plug and play devices. An “output device” includes, but is not limited to: display devices, and other devices for outputting information and functions.

“Logic circuitry,” as used herein, includes, but is not limited to, hardware, firmware, a non-transitory computer readable medium that stores instructions, instructions in execution on a machine, and/or to cause (e.g., execute) an action(s) from another logic circuitry, module, method and/or system. Logic circuitry can include and/or be a part of a processor controlled by an algorithm, a discrete logic (e.g., ASIC), an analog circuit, a digital circuit, a programmed logic device, a memory device containing instructions, and so on. Logic can include one or more gates, combinations of gates, or other circuit components. Where multiple logics are described, it can be possible to incorporate the multiple logics into one physical logic. Similarly, where a single logic is described, it can be possible to distribute that single logic between multiple physical logics.

“Memory,” as used herein can include volatile memory and/or nonvolatile memory. Non-volatile memory can include, for example, ROM (read only memory), PROM (programmable read only memory), EPROM (erasable PROM), and EEPROM (electrically erasable PROM). Volatile memory can include, for example, RAM (random access memory), synchronous RAM (SRAM), dynamic RAM (DRAM), synchronous DRAM (SDRAM), double data rate SDRAM (DDRSDRAM), and direct RAM bus RAM (DRRAM). The memory can store an operating system that controls or allocates resources of a computing device.

“Operable connection,” or a connection by which entities are “operably connected,” is one in which signals, physical communications, and/or logical communications can be sent and/or received. An operable connection can include a wireless interface, a physical interface, a data interface, and/or an electrical interface.

“Module”, as used herein, includes, but is not limited to, non-transitory computer readable medium that stores instructions, instructions in execution on a machine, hardware, firmware, software in execution on a machine, and/or combinations of each to perform a function(s) or an action(s), and/or to cause a function or action from another module, method, and/or system. A module can also include logic, a software controlled microprocessor, a discrete logic circuit, an analog circuit, a digital circuit, a programmed logic device, a memory device containing executing instructions, logic gates, a combination of gates, and/or other circuit components. Multiple modules can be combined into one module and single modules can be distributed among multiple modules.

“Portable device”, as used herein, is a computing device typically having a display screen with user input (e.g., touch, keyboard) and a processor for computing. Portable devices include, but are not limited to, handheld devices, mobile devices, smart phones, laptops, tablets and e-readers.

“Processor,” as used herein, processes signals and performs general computing and arithmetic functions. Signals processed by the processor can include digital signals, data signals, computer instructions, processor instructions, messages, a bit, a bit stream, that can be received, transmitted and/or detected. Generally, the processor can be a variety of various processors including multiple single and multicore processors and co-processors and other multiple single and multicore processor and co-processor architectures. The processor can include logic circuitry to execute actions and/or algorithms.

“Vehicle,” as used herein, refers to any moving vehicle that is capable of carrying one or more human occupants and is powered by any form of energy. The term “vehicle” includes, but is not limited to cars, trucks, vans, minivans, SUVs, motorcycles, scooters, boats, go-karts, amusement ride cars, rail transport, personal watercraft, and aircraft. In some cases, a motor vehicle includes one or more engines. Further, the term “vehicle” can refer to an electric vehicle (EV) that is capable of carrying one or more human occupants and is powered entirely or partially by one or more electric motors powered by an electric battery. The EV can include battery electric vehicles (BEV) and plug-in hybrid electric vehicles (PHEV). The term “vehicle” can also refer to an autonomous vehicle and/or self-driving vehicle powered by any form of energy. The autonomous vehicle can carry one or more human occupants. Further, the term “vehicle” can include vehicles that are automated or non-automated with pre-determined paths or free-moving vehicles.

“Vehicle display”, as used herein can include, but is not limited to, LED display panels, LCD display panels, CRT display, plasma display panels, touch screen displays, among others, that are often found in vehicles to display information about the vehicle. The display can receive input (e.g., touch input, keyboard input, input from various other input devices, etc.) from a user. The display can be located in various locations of the vehicle, for example, on the dashboard or center console. In some embodiments, the display is part of a portable device (e.g., in possession or associated with a vehicle occupant), a navigation system, an infotainment system, among others.

“Vehicle control system” and/or “vehicle system,” as used herein can include, but is not limited to, any automatic or manual systems that can be used to enhance the vehicle, driving, and/or safety. Exemplary vehicle systems include, but are not limited to: an electronic stability control system, an anti-lock brake system, a brake assist system, an automatic brake prefill system, a low speed follow system, a cruise control system, a collision warning system, a collision mitigation braking system, an auto cruise control system, a lane departure warning system, a blind spot indicator system, a lane keep assist system, a navigation system, a transmission system, brake pedal systems, an electronic power steering system, visual devices (e.g., camera systems, proximity sensor systems), a climate control system, an electronic pretensioning system, a monitoring system, a passenger detection system, a vehicle suspension system, a vehicle seat configuration system, a vehicle cabin lighting system, an audio system, a sensory system, an interior or exterior camera system among others.

I. System Overview

The systems and methods described herein are generally directed to controlling a vehicle using a vehicle communication network that can include multiple vehicles and infrastructures. Communicating information using a vehicle communication network and/or sensing information allows for synergistic control of one or more vehicles in the context of a traffic scenario. In particular, the methods and systems described herein provide Cooperative Adaptive Cruise Control (C-ACC), hazard detection, and merge assistance using a vehicle communication network. FIG. 1A illustrates an exemplary traffic scenario 100 that will be used to describe some of the systems and methods herein. The traffic scenario 100 involves one or more vehicles on a roadway 102. The roadway 102 has a first lane 104 a, a second lane 104 b, and a third lane 104 c. It is understood that the roadway 102 can have various configurations not shown in FIG. 1A, and can have any number of lanes.

In FIG. 1A, the traffic scenario 100 includes a host vehicle (HV) 106 and one or more remote vehicles, which will generally be referred to as remote vehicles 108. However, more specifically, the remote vehicles 108 include a remote vehicle (RV) 108 a, a remote vehicle 108 b, a remote vehicle 108 c, a remote vehicle 108 d, a remote vehicle 108 e, a remote vehicle 108 f, and a remote vehicle 108 g. The one or more remote vehicles 108 can also be referred to as a plurality of remote vehicles 108. In some embodiments, one or more of the remote vehicles 108 can be identified with respect to the host vehicle 106. For example, the remote vehicle 108 d can be identified as a preceding vehicle in relation to the host vehicle 106. Specifically, the remote vehicle 108 d is a preceding vehicle located immediately in front or immediately ahead of the host vehicle 106. In some embodiments, one of the remote vehicles 108 can be a leading vehicle, which is a remote vehicle ahead of a host vehicle and a preceding vehicle. For example, in FIG. 1A a leading vehicle can be identified as the remote vehicle 108 a, which is ahead of the host vehicle 106 and the preceding vehicle 108 d. In other embodiments, the leading vehicle can be the remote vehicle 108 b.

In some embodiments, one or more of the remote vehicles 108 in the traffic scenario 100 can be identified as a platoon of vehicles 108. For example, the host vehicle 106, the remote vehicle 108 a, the remote vehicle 108 b, the remote vehicle 108 c, and the remote vehicle 108 d can be part of a platoon of vehicles 108 travelling in the same lane (i.e., the second lane 104 b). FIG. 1B is a schematic view of the remote vehicles 108 travelling in the second lane 104 b of FIG. 1A, namely, the host vehicle 106, the remote vehicle 108 a, the remote vehicle 108 b, the remote vehicle 108 c, and the remote vehicle 108 d. In some embodiments, the string of vehicles shown in FIG. 1B can be a platoon of vehicles 108. It is understood that the host vehicle 106 and the remote vehicles 108 can be in different configurations and positions other than those shown in FIGS. 1A and 1B.

In the systems and methods discussed herein, the host vehicle 106 can be controlled, in part, based on data about the one or more remote vehicles 108 communicated via a vehicle communication network. The host vehicle 106 and one or more of the remote vehicles 108 can communicate as part of a vehicle communication network. In particular, the vehicle communication described herein can be implemented using Dedicated Short Range Communications (DSRC). However, it is understood that the vehicle communication described herein can be implemented with any communication or network protocol, for example, ad hoc networks, wireless access within the vehicle, cellular networks, Wi-Fi networks (e.g., IEEE 802.11), Bluetooth, WAVE, CALM, among others. Further, the vehicle communication network can be vehicle-to-vehicle (V2V) or a vehicle-to-everything (V2X).

In FIG. 1A, the host vehicle 106 can transmit, receive, and/or exchange communications including data, messages, images, and/or other information with other vehicles, user, or infrastructures, using DSRC. In particular, the host vehicle 106 is equipped with a vehicle-to-vehicle (V2V) transceiver 110 that can exchange messages and information with other vehicles, users, or infrastructures that are operable for computer communication with the host vehicle 106. For example, the V2V transceiver 110 can communicate with the remote vehicle 108 a via a V2V transceiver 112 a, the remote vehicle 108 b via a V2V transceiver 112 b, the remote vehicle 108 c via a V2V transceiver 112 c, and the remote vehicle 108 g via a V2V transceiver 112 d. The V2V transceiver 110 can also communicate with a wireless network antenna 114 and/or a roadside equipment (RSE) 116. Similarly, the remote vehicle 108 a, the remote vehicle 108 b, the remote vehicle 108 c, and the remote vehicle 108 g can use its respective V2V transceiver to communicate with one another, the host vehicle 106, the wireless network antenna 114, and/or the RSE 116. In the embodiment shown in FIG. 1A, the remote vehicle 108 d, the remote vehicle 108 e, and the remote vehicle 108 f are not equipped (e.g., do not have DSRC V2V transceivers) for communication with the host vehicle 106 using the vehicle communication network. It is understood that in other embodiments, one or more of the remote vehicle 108 d, the remote vehicle 108 e, and the remote vehicle 108 f can include equipment for communication with the host vehicle 106 using the vehicle communication network.

As will be discussed herein, various types of data can be communicated using the vehicle communication network. For example, the type and/or specifications of the vehicle, navigation data, roadway hazard data, traffic location data, course heading data, course history data, projected course data, kinematic data, current vehicle position data, range or distance data, speed and acceleration data, location data, vehicle sensory data, vehicle subsystem data, and/or any other vehicle information. Some of the embodiments discussed herein include exchanging data and information between networked vehicles for use in vehicle driving. More specifically, control of a vehicle can be executed based in part on the communicated data. Accordingly, DSRC communication can be used to control one or more vehicle control systems. Vehicle control systems include, but are not limited to, cooperative adaptive cruise control (C-ACC) systems, adaptive cruise control (ACC) systems, intelligent cruise control systems, autonomous driving systems, driver-assist systems, lane departure warning systems, merge assist systems, freeway merging, exiting, and lane-change systems, collision warning systems, integrated vehicle-based safety systems, and automatic guided vehicle systems. Some of the embodiments herein are described in the context of a C-ACC system, a vehicle control system, and/or a merge assist system.

Additionally, in the systems and methods discussed herein, the host vehicle 106 can be controlled, in part, based on data about the one or more remote vehicles 108 sensed by the host vehicle 106. In FIG. 1A, each of the remote vehicles 108 on the roadway 102 can sense proximate vehicles and objects, which is illustrated by the accurate lines emanated from the remote vehicles 108. The remote vehicles 108 can sense proximate vehicles and objects using one or more sensors (e.g., radar sensors). The host vehicle 106 can include one or more sensors, which will be discussed in further detail herein, for sensing data about other vehicles and objects in proximity to the host vehicle 106. For example, the host vehicle 106 can sense distance, acceleration, and velocity about the preceding vehicle 108 d or other vehicles proximate to the host vehicle 106. Accordingly, although the preceding vehicle 108 d is not equipped for V2V communication with the host vehicle 106, the host vehicle 106 can still obtain data about the preceding vehicle 108 d using on-board sensors.

A. Vehicle Communication Network

Referring now to FIG. 2, a schematic view of a vehicle communication network 200 according to an exemplary embodiment is shown. The vehicle communication network 200 can be implemented within the vehicles shown in FIGS. 1A and 1B. In FIG. 2, the host vehicle 106 includes a C-ACC system 202. The C-ACC system 202 can exchange vehicle and traffic data with other DSRC compatible vehicles via V2V transceiver 110. For example, the V2V transceiver 110 can exchange data with the remote vehicle 108 a via the V2V transceiver 112 a using a communication link 203. Although only one remote vehicle is shown in FIG. 2, it is understood that the host vehicle 106 can communicated with more than one remote vehicle configured for DSRC communication within the vehicle communication network 200. Thus, is some embodiments, communication links using DSRC can be established between the host vehicle 106 and a plurality of remote vehicles (e.g., the remote vehicles 108) configured for V2V communication using DSRC.

In the embodiments discussed herein, control of the host vehicle 106 is executed based on information communicated directly between the host vehicle 106 and one or more of the remote vehicles 108. However, in some embodiments, data can be exchanged with other infrastructures and servers. For example, in FIG. 2, the C-ACC system 202 can transmit and receive information directly or indirectly to and from a service provider 212 over a wireless communication network 204. The service provider 212 can include a remote server 214, a remote transmitter 216, a remote receiver 218, and a remote memory 220 that are configured to be in communication with one another. In one embodiment, the host vehicle 106 can receive data and information from the service provider 212 by way of a one-to-many communication network 222. The one-to-many communication network 222 can include systems that can send information from one source to a plurality of receivers. Examples of one-to-many communication networks can include television, radio, satellite networks, among others.

In FIG. 2, the V2V transmitter 110 can be used by the C-ACC system 202 to receive and transmit information to and from the service provider 212 and other information providers through the wireless communication network 204 and a broadband network 210, such as the Internet. In alternative embodiments, a radio frequency (RF) transceiver 224 in host vehicle 106 can be used by the C-ACC system 202 to receive and transmit information to and from the service provider 212 through wireless network antenna 114 to the wireless communication network 204. The RF transmitter 224 can include, but is not limited to, a wireless phone, a wireless modem, a Wi-Fi compatible transceiver, and/or any other device that communicates with other networks using the wireless communication network 204. The host vehicle 106 can also receive and transmit information to and from a traffic data supplier 206 and/or one or more other information suppliers 208. This information can include, but is not limited to, traffic data, vehicle location and heading data, high-traffic event schedules, weather data, or other transport related data, etc. The traffic data supplier 206 and the other information supplier 208 can communicate with the service provider 212 through the broadband network 210.

In some embodiments, the service provider 212 can be linked to multiple vehicles through a network connection, such as via the wireless network antenna 114 (FIG. 1A), and/or other network connections. Further, any other wireless communication system capable of delivering data may be used such as satellite, cellular, Wi-Fi, microwave, etc. The service provider 212 may also be linked by a wired connection, such as broadband cable or fiber optic connections, Ethernet, DSL, ADSL, telephone modems, and/or any other wired communication system capable of delivering data to traffic infrastructure such as RSE 116.

B. Vehicle System and C-ACC Overview

The host vehicle 106 and the C-ACC system 202 will now be described in more detail with reference to FIG. 3. FIG. 3 is a block diagram of an exemplary control system 300 of the host vehicle 106. However, the components and functionalities shown in FIG. 3 can be associated with other vehicles. For example, the remote vehicles 108 can include one or more of the components and functionalities of the control system 300. Thus, the control system 300 can be alternatively use the system by other entities or in other applications. Further, in some embodiments, the control system 300 will be referred to as a C-ACC control system (e.g., the C-ACC system 202). Other C-ACC systems associated with some vehicles may include different elements and/or arrangements as configured to the C-ACC system 202, but can be configured to communicate over the vehicle communication network 200 with one or more other C-ACC systems, vehicle control systems, or merge assist systems.

The host vehicle 106 can have one or more computers and or computing devices, for example, in FIG. 3, the control system 300 includes a vehicle computer system 302. In some embodiments discussed herein, the vehicle computer system 302 will be referred to as a C-ACC computer system 302. In other embodiments, the vehicle computer system 302 can be associated with another type of vehicle control system or can be a general vehicle computing device that facilitates the functions described herein.

The vehicle computer system 302 includes a processor 304 and a memory 306. In some embodiments, the vehicle computer system 302 may include programmable logic circuits and/or pre-configured logic circuits for executing C-ACC system functions and/or merge assist system functions. The memory 306 stores information accessible by the processor 304 including instructions 308 and data 310 that may be executed or otherwise used by the processor 304. The control logic (in this example, software instructions or computer program code), when executed by the processor 304, causes processor 304 to perform the functions of the embodiments as described herein. The memory 306 may be of any type capable of storing information accessible by the processor 304, including a computer-readable medium, or other medium that stores data that may be read with the aid of an electronic device, such as a hard-drive, flash drive, memory card, ROM, RAM, DVD or other optical disks, as well as other write-capable and read-only memories. Systems and methods may include different combinations of the foregoing, whereby different portions of the instructions and data are stored on different types of media.

The instructions 308 may be any set of instructions to be executed directly (such as machine code) or indirectly (such as scripts) by the processor 304. For example, the instructions may be stored as computer code on the computer-readable medium. In this regard, the terms “instructions” and “programs” may be used interchangeably herein. The instructions may be stored in object code format for direct processing by the processor 304, or in any other computer language including scripts or collections of independent source code modules that are interpreted on demand or compiled in advance. Functions, methods and routines of the instructions are explained in more detail below.

The data 310 may be retrieved, stored or modified by the processor 304 in accordance with the instructions 308. For instance, although the vehicle computer system 302 is not limited by any particular data structure, the data 310 may be stored in computer registers, in a relational database as a table having a plurality of different fields and records, XML documents or flat files. The data 310 may also be formatted in any computer-readable format. The data 310 may include any information sufficient to identify the relevant information, such as numbers, descriptive text, proprietary codes, references to data stored in other areas of the same memory or different memories (including other network locations) or information that is used by a function to calculate the relevant data.

In FIG. 3, the data 310 can include traffic data 312, map component data 314, traffic assist data 316, and merge models 318. The traffic data 312 can include commercially-available databases of transport data, traffic data, and traffic schedules, among others. The map component data 314 can include maps identifying the shape and elevation of roadways, lane lines, intersections, crosswalks, bicycle lanes, school zones, speed limits, traffic signals, buildings, signs, real time traffic information, or other transport information that can be used by vehicles. For example, the map component data 314 may include one or more mapped networks of information, such as roadways, lanes, intersections, and the connections between these features. Each feature may be stored as map component data 314, and may be associated with information, such as a geographic location, and whether or not it is linked to other related features, e.g., dimensions of a widened merge lane may be linked to a roadway location and an entrance ramp, among others. The traffic assist data 316, which will be discussed in further detail herein, can include traffic data from various sources within and external to host vehicle 106. Further, the merge models 318 can include types of merge scenarios for merge assistance as will be discussed below in Section IV.

The vehicle computer system 302 can communicate with various components of the host vehicle 106. For example, the vehicle computer system 302 can communicate with the vehicle electronic control unit (ECU) 320, and can send and receive information from the various systems of host vehicle 106, for example vehicle sensor systems 322, a vehicle communication system 324, a vehicle navigation system 326, and a vehicle interface system 328. When engaged, the vehicle computer system 302 can control some or all of these functions of host vehicle 106. It is understood that, although various systems and vehicle computer system 302 are shown within host vehicle 106, these elements may be external to host vehicle 106 and/or physically separated by large distances. Further, the vehicle computer system 302 can be operable connected for computer communication to other components of the host vehicle 106 via, for example, a bus 330.

The vehicle sensor system 322 includes various vehicle sensors that sense and/or measure data internally and/or externally from the host vehicle 106. More specifically, the vehicle sensor system 322 can include vehicle sensors for sensing and measuring a stimulus (e.g., a signal, a property, a measurement, a quantity) associated with the host vehicle 106 and/or a particular vehicle system of the host vehicle 106. In some embodiments, the vehicle sensors are for sensing and measuring a stimulus associated with a vehicle and/or an object in proximity to the host vehicle 106. The vehicle sensor system 322 and the various vehicle sensors will be discussed in more detail herein with FIG. 4.

As indicated above, the host vehicle 106 may also include the vehicle communication system 324. The vehicle computer system 302 can communicate with external communication apparatus for sending and receiving data. For instance, the vehicle communication system 324 includes the V2V transceiver 110 that can communicate with compatible DSRC transceivers in the vehicle communication network 200. As described previously in relation to FIG. 2, the vehicle communication system 324 can include the RF transceiver 224 for communicating wirelessly to service provider 212 through wireless communication network 204. It is understood that some vehicles may not be equipped with communication equipment for V2V and/or V2X communication using DSRC or another type of communication protocol. For example, the remote vehicle 108 d, the remote vehicle 108 e, and the remote vehicle 108 f shown in FIG. 1A are not equipped with a V2V transceiver that can communicate with compatible DSRC transceivers in the vehicle communication network 200.

The host vehicle 106 also includes the vehicle navigation system 326. The vehicle navigation system 326 can provide navigation maps and information to the host vehicle 106 and/or the vehicle computer system 302. The vehicle navigation system 436 may be any type of known, related or later developed navigational system and may include a GPS unit (not shown). The phrase “navigation information” refers to any information that can be used to assist host vehicle 106 in navigating a roadway or path. Navigation information may include traffic data, map data, and roadway classification information data. Examples of navigation information can include street addresses, street names, street or address numbers, intersection information, points of interest, parks, bodies of water, any political or geographical subdivision including town, township, province, prefecture, city, state, district, ZIP or postal code, and country. Navigation information can also include commercial information including business and restaurant names, commercial districts, shopping centers, and parking facilities. Navigation information can also include geographical information, including information obtained from any Global Navigational Satellite infrastructure (GNSS), including Global Positioning System or Satellite (GPS), Glonass (Russian) and/or Galileo (European).

Further, the host vehicle 106 includes a vehicle interface system 328 that can be used to receive input from a user and/or provide feedback to the user. Accordingly, the vehicle interface system 328 can include a display portion and an input portion. In some embodiments, the vehicle interface system 328 is a human machine interface (HMI) and/or a heads-up display (HUD) located in the host vehicle 106. The vehicle interface system 328 can receive one or more user inputs from one or more users (e.g., a driver, vehicle occupants). The input portion of the vehicle interface system 328 may enable a user, such as a driver or vehicle occupant, to interact with or provide input, such as user input, gestures, clicks, points, selections, voice commands, etc. the host vehicle 106 and/or the vehicle computer system 302. For example, in some embodiments a user can enable the vehicle computer system 302 and/or control features of the vehicle computer system 302 by interacting with the vehicle interface system 328.

As an example, the input portion of the vehicle interface system 328 can be implemented as a touch screen, a touchpad, a track pad, one or more hardware buttons (e.g., on a radio or a steering wheel), one or more buttons, such as one or more soft buttons, one or more software buttons, one or more interactive buttons, one or more switches, a keypad, a microphone, one or more sensors, etc. In one or more embodiments, the vehicle interface system 328 can be implemented in a manner which integrates a display portion such that the vehicle interface system 328 both provides an output (e.g., renders content as the display portion) and receives inputs (e.g., user inputs). An example of this can be a touch screen. Other examples of input portions may include a microphone for capturing voice input from a user.

The vehicle interface system 328 can display information (e.g., graphics, warnings, and notifications). For example, the vehicle computer system 302 can generate information, suggestions, warnings, and/or alerts and provide the same to a vehicle operator on a display device (e.g., display portion) of the vehicle interface system 328. The information, warnings, etc., can include, but are not limited to, one or more navigation maps, symbols, icons, graphics, colors, images, photographs, videos, text, audible information, among others. The vehicle interface system 328 can also include other systems that provide visual, audible, and/or tactile/haptic feedback to a user. For example, an active force pedal (AFP) can be included as part of an acceleration pedal in the host vehicle 106 to provide active feedback force to a driver's foot as the driver pushes the acceleration pedal.

The host vehicle 106 may include other apparatus for communicating, and in some cases controlling, the various components associated with vehicle systems. The various vehicle systems that the host vehicle 106 can control and/or communicate with will now be discussed in greater detail with reference to FIG. 4. FIG. 4 is a schematic view of the host vehicle 106 including vehicle systems and components that can be associated with the vehicle control system 300 of FIG. 3. As mentioned above with FIG. 3, the components and functionalities shown in FIG. 4 can be associated with other vehicles. For example, the remote vehicles 108 can include one or more of the components and functionalities shown in FIG. 4.

In FIG. 4, the ECU 320 can communicate with a data logger system 402, one or more vehicle systems 404, the vehicle navigation system 326, the vehicle sensor system 322, the vehicle V2V transceiver 110, the RF transceiver 224, a camera 416 and a laser 418. In some embodiments discussed herein, the ECU 320 is configured to receive instructions from the vehicle computer system 302 to retrieve data from one or more components shown in FIG. 4. For example, the ECU 320 can receive instructions from the C-ACC computer system 302 for commands to activate or suppress a particular vehicle system 404, for example, a brake or accelerator, according to an acceleration control rate.

The data logger system 402 can communicate with the ECU 320 to acquire and log data collected from any of the vehicle systems 404 and/or the vehicle sensor system 416. As discussed above, the host vehicle 106 can include the vehicle navigation system 326 that is configured to be in communication with the ECU 320. The navigation system 326 can include a GPS receiver 406, a navigation system display 408 (e.g., part of the vehicle interface system 328), and can store map and location information in a navigation database 410. The navigation system display 408 can display navigational maps and information to a user using any type of display technology. The navigation system display 408 may also communicate information to the host vehicle 106 using any type of known, related art or later developed audio technology, such as by using predetermined sounds or electronically generated speech.

As mentioned above, the vehicle sensor system 322 can include various vehicle sensors and can communicate with the ECU 320 and any number of vehicle sensor devices in any configuration. The vehicle sensor system 322 devices can be advantageous by collecting data for identification and tracking the movement of traffic entities such as the remote vehicles 108, vehicular traffic, or any other condition, entity, or vehicle that could provide data. It is understood that the vehicle sensors can be any sensor used in any vehicle system for detecting and/or sensing a parameter of that system. Exemplary vehicle sensors include, but are not limited to: acceleration sensors, speed sensors, braking sensors, proximity sensors, vision sensors, seat sensors, seat-belt sensors, door sensors, environmental sensors, yaw rate sensors, steering sensors, GPS sensors, among others.

It is also understood that the vehicle sensors can be any type of sensor, for example, acoustic, electric, environmental, optical, imaging, light, pressure, force, thermal, temperature, proximity, among others. The vehicle sensors could be disposed in one or more portions of the host vehicle 106. For example, the vehicle sensors could be integrated into a dashboard, seat, seat belt, door, bumper, front, rear, corners, dashboard, steering wheel, center console, roof or any other portion of the host vehicle 106. In other cases, however, the vehicle sensors could be portable sensors worn by a driver (not shown), integrated into a portable device (not shown), carried by the driver (not shown), integrated into an article of clothing (not shown) worn by the driver or integrated into the body of the driver (e.g. an implant) (not shown).

Referring now to the exemplary vehicle sensors in FIG. 4, the vehicle sensor system 322 can include a sensor 412, a radar system 414, the camera 416, and the laser 418, each of which can be disposed at any beneficial area of the host vehicle 106. Although one sensor 418 is shown in FIG. 4, it is understood that sensor 418 is a representation of one or more sensors installed within or outside of the host vehicle 106. In some embodiments, the vehicle sensor 418 sense vehicle speed, acceleration rate, braking rate, and other vehicle dynamics data about the host vehicle 106. In some embodiments, the vehicle sensor 418 can collect proximity data using rear, front, and side proximity detection sensors 418.

The radar system 414 can include a front long range radar and/or a front midrange radar. The front long range radar can measure distance (e.g., lateral, longitudinal) and speed of objects surrounding the host vehicle 106. For example, the front long range radar can measure distance and speed of one or more of the remote vehicles 108 surrounding the host vehicle 106. In some embodiments, the radar system 414 can include a plurality of radars in different location of the host vehicle 106. For example, a front left radar located at a front left corner area of the host vehicle 106, a front right radar located at a front right corner area of the host vehicle 106, a rear left radar located at a rear left corner area of the host vehicle 106, and a rear right radar located at a rear right corner area of the host vehicle 106.

FIG. 4 also shows the V2V transceiver 110 of the host vehicle 106 for communicating with other V2V compatible vehicles. In an embodiment, V2V transceiver 110 can collect traffic data from other DSRC transceivers that can be configured for a vehicle, pedestrian, bicycle, building, tower, billboard, traffic signal, roadway sign, or any transport related entity or user. A display operationally connected to a DSRC transceiver can also display any messages, maps, vehicle locations, data, images, alerts, and warnings transmitted to or received from DSRC users in vehicle communication network 200. A communication link (e.g., the communication link 203 in FIG. 2) between DSRC transceivers may be initiated by any user. In the embodiments, a DSRC transceiver may continuously search for signals from other DSRC transceivers, such as by emitting a periodic signal that searches for a reply. In other embodiments, a DSRC transceiver may emit periodic signals searching for a reply from an in-range DSRC transceiver. If a DSRC transceiver replies, then a communications link may be established. Information and data received by the host vehicle 106 can be saved to data logger system 402 and/or the data 310 and processed by the vehicle computer system 302.

An exemplary interior view of the host vehicle 106 is shown in FIG. 5. Specifically, FIG. 5 is a schematic of an exemplary design of a vehicle interior 500 associated with the host vehicle 106 and the vehicle control system 300 of FIG. 3. The vehicle interior 500 may include, for example, a dashboard 502, a steering apparatus such as a steering wheel 504, an instrument panel 506, and a center portion 508. The center portion 508 can include one or more devices associated with the interior of the vehicle, including but are not limited to: audio devices, video devices, navigation devices, as well as any other types of devices. In addition, the center portion 508 can be associated with controls for one or more systems of the host vehicle 106 including, but not limited to: climate control systems, radio and sound systems, and other types of systems.

The host vehicle 106 may also have a display device 510, which can be part of the vehicle interface system 328 for displaying information from the vehicle control system 300, and/or other related or unrelated vehicular systems. Examples of display device 510 include, but are not limited to, LCDs, CRTs, ELDs, LEDs, OLEDs, or electronic paper displays each with or without a touchscreen, as well as other types of displays. The display device 510 can include a touchscreen for use as a user input device for the vehicle interface system 328. For example, using the vehicle interface system 328 a user can activate or deactivate one or C-ACC system modes, merge assist modes, and for enabling a user to provide information, such as navigation destination or traffic information, to the vehicle computer system 302.

In alternative embodiments, the vehicle interface system 328 can include buttons, a keypad, or other types of input devices. In another embodiment, the vehicle interface system 328 can include a heads up projection (HUD) type display that is configured to project an image onto one or more surfaces of the host vehicle 106, such as windshield 512. In some embodiments, the display device 510 can be located in any portion of the host vehicle 106, or can be a portable device (not shown). For example, display device 510 can be located within instrument panel 506.

In addition, as discussed above with FIG. 3, the display device 510 can be configured to present visual information for the vehicle computer system 302 and other devices or systems within the host vehicle 106, such as the vehicle navigation system 326. For example, vehicle interface system 328 can inform a driver with visual or auditory alerts or information of traffic flow, hazard detection, a predicted traffic merge by another vehicle, among others. For example, the display device 510 can be configured to display hazard alerts, merge alerts, and traffic data related to one or more of the remote vehicles 108 when one or more of the remote vehicles 108 would affect the operation of the host vehicle 106. Additionally in FIG. 5, an acceleration pedal 514 and a brake pedal 516 are shown. As discussed above, in some embodiments, the acceleration pedal 514 can include an active force pedal (AFP) that can provide active feedback force to a driver's food as the driver pushes the acceleration pedal 514.

C. C-ACC Control Model

As mentioned above, in some embodiments, the systems and methods discussed herein control the host vehicle 106 using data about the host vehicle 106 and data about one or more of the remote vehicles 108. The data about one or more of the remote vehicles 108 can be received by the C-ACC control system 300 using the vehicle communication network 200. In some embodiments, the data about one or more of the remote vehicles 108 can be received by the C-ACC control system 300 using sensors (e.g., radar sensors) on-board the host vehicle 106. Fusion and analysis of this data can be used to control the host vehicle 106 thereby allowing the host vehicle 106 to preemptively react to a traffic scenario and one or more of the remote vehicles 108 that may affect the operation or the travel path of the host vehicle 106. Exemplary control by the C-ACC control system 300 will now be described in greater detail.

In some of the embodiments discussed herein, motion of the host vehicle 106 can be controlled, for example, by the C-ACC control system 300. In particular, the C-ACC control system 300 can control longitudinal motion of the host vehicle 106 using the data discussed above. For example, the C-ACC control system 300 can control acceleration and/or deceleration by generating an acceleration control rate and/or modifying a current acceleration control rate (e.g., a target acceleration rate). By using the data discussed above, the C-ACC control system 300 can assess a dynamic state of the host vehicle 106 and the remote vehicles 108 and accordingly adapt control of the host vehicle 106. Referring now to FIG. 6, a schematic C-ACC control model 600 for controlling a vehicle control system is shown. FIG. 6 will be described with reference to the components of FIGS. 2-5. The control model 600 receives as inputs host vehicle data 602, V2V remote vehicle data 604, and sensed remote vehicle data 606. The host vehicle data 602 includes vehicle dynamics data about the host vehicle 106. For example, speed, acceleration, velocity, yaw rate, steering angle, throttle angle, range or distance data, among others. The host vehicle data 602 can be accessed from the vehicle sensor system 322 via the bus 330. The host vehicle data 602 can also include status information about different vehicle systems. For example, the host vehicle data 602 can include turn signal status, course heading data, course history data, projected course data, kinematic data, current vehicle position data, and any other vehicle information about the host vehicle 106.

The V2V remote vehicle data 604 includes remote vehicle dynamics data about one or more of the remote vehicles 108 communicated via the vehicle communication network 200. The V2V remote vehicle data 604 can include speed, acceleration, velocity, yaw rate, steering angle, and throttle angle, range or distance data, among others, about one or more of the remote vehicles 108. The V2V remote vehicle data 604 can also include course heading data, course history data, projected course data, kinematic data, current vehicle position data, and any other vehicle information about the remote vehicle 108 that transmitted the V2V remote vehicle data 604.

The sensed remote vehicle data 606 can include data about one or more of the remote vehicles 108 and/or other objects in proximity to the host vehicle 106, received and/or sensed by the vehicle system sensors 322. For example, in the embodiments discussed herein, the sensed remote vehicle data 606 includes vehicle data obtained from the radar system 414 including proximity data. For example, the sensed remote vehicle data 606 can include distance and speed of one or more of the remote vehicles 108 surrounding the host vehicle 106.

The host vehicle data 602, the V2V remote vehicle data 604, and the sensed remote vehicle data 606 can be input to the C-ACC computer system 302 and processed using a control algorithm, which will be described in further detail herein. The C-ACC computer system 302 can output acceleration and/or deceleration commands to the ECU 320, which then executes said commands to the respective vehicle system, for example, a brake actuator 608 (e.g., that can be part of a brake assist system) and/or a throttle actuator 610. For example, based on the host vehicle data 602, the V2V remote vehicle data 604, and the sensed remote vehicle data 606, the C-ACC computer system 302 can generate an acceleration control rate, which can be a target acceleration rate for the host vehicle 106. Based on the current acceleration rate of the host vehicle 106, the C-ACC computer system 302 can generate a control signal to achieve the acceleration control rate. The control signal can be sent to the ECU 320, which then executes the signal, for example, by controlling the brake actuator 608 and/or the throttle actuator 610.

Additionally, the C-ACC computer system 302 and/or the ECU 320 can execute commands to the HMI 612 (e.g., the vehicle interface system 328). For example, based on the host vehicle data 602, the V2V remote vehicle data 604, and the sensed remote vehicle data 606, visual, audible and/or tactile feedback can be generated and provided via the HMI 612. Accordingly, the host vehicle 106 is controlled based on the fusion of the host vehicle data 602, the V2V remote vehicle data 604, and the sensed remote vehicle data 606 in accordance with the control algorithm, which will now be described in further detail.

The C-ACC computer system 302 implements a control algorithm to generate an acceleration control rate that can be used to control the host vehicle 106 in relation to one or more of the remote vehicles 108, namely, a preceding vehicle and a leading vehicle. For example, with reference to FIG. 1B, the host vehicle 106 can be controlled in relation to the leading vehicle 108 a and the preceding vehicle 108 d. The control algorithm can include a distance control component based on the relative distance between the host vehicle 106 and the preceding vehicle 108 d and a headway reference distance. The distance control component can be expressed mathematically as:

a _(x) _(ref) =K _(p)(x _(i-1) −x _(i) −h{dot over (x)} _(i) −L _(PV))  (1)

where x_(i-1) is a distance from a rear end of the host vehicle 106 to the front end of the preceding vehicle 108 d, x_(i) is a length of the host vehicle 106, h{dot over (x)}_(i) is a pre-determined headway reference distance and L_(PV) is the length of the preceding vehicle 108 d. These variables are schematically shown in FIG. 1B. The control algorithm can also include a velocity control component based on the relative velocity between the host vehicle 106 and the preceding vehicle 108 d. Accordingly, in one embodiment, the velocity control component can be expressed mathematically as:

a _(v) _(ref) =K _(v)(v _(i-1) −v _(i))  (2)

where v_(i-1) is a velocity of the preceding vehicle 108 d, v_(i) is the velocity of the host vehicle 106, and K_(v) is a vehicle speed dynamic gain coefficient. In some embodiments, the acceleration control rate is calculated based on the distance control component and the velocity control component, which can be expressed mathematically as:

a _(xv) _(ref) =K _(p)(x _(i-1) −x _(i) −h{dot over (x)} _(i) −L _(PV))+K _(v)(v _(i-1) −v _(i))  (3)

In one embodiment, an acceleration control reference based on acceleration data communicated via the vehicle communication network 200 can be calculated and used as a feedforward control input to the acceleration control reference based on the distance component and the velocity component discussed above in equation (3). More specifically, in one embodiment, the control algorithm includes an acceleration control component based on acceleration data of the leading vehicle 108 a and acceleration data of the preceding vehicle 108 d. The acceleration data about the leading vehicle 108 a is V2V remote vehicle data received using the vehicle communication network 200 (e.g., via DSRC). In one embodiment, the acceleration data about the preceding vehicle 108 d is sensed remote vehicle data received using sensors on-board the host vehicle 106, for example, the radar system 414. Accordingly, in one embodiment, the acceleration control reference based on acceleration data communicated via the vehicle communication network can be expressed mathematically as:

a _(DSRC) _(ref) =K _(a) _(PV) ·a _(i-1) +K _(dsrc) ·a _(L)  (4)

where a_(i-1) is an acceleration rate of the preceding vehicle 108 d detected by the radar system 414, K_(a) _(PV) is a preceding vehicle acceleration dynamic gain coefficient, a_(L) is an acceleration rate of the leading vehicle 108 a received by the host vehicle 106 from the leading vehicle 108 a using DSRC via the vehicle communication network 200, and K_(dsrc) is a leading vehicle acceleration dynamic gain coefficient. In the examples discussed herein, the acceleration rate of the preceding vehicle 108 d is sensed remote vehicle data 606 (e.g., radar data detected using radar sensors), but it is understood that in other embodiments the acceleration rate of the preceding vehicle 108 d can be V2V remote vehicle data received by the host vehicle 106 using DSRC via the vehicle communication network 200. Based on the above, an acceleration control rate can be generated by the C-ACC computer system 302 using the distance component, the velocity component, the acceleration component of the preceding vehicle 108 d, and the acceleration component of the leading vehicle 108 a. This can be expressed mathematically as,

a _(ref) =K _(p)(x _(i-1) −x _(i) −h{dot over (x)} _(i) −L _(PV))+K _(v)(v _(i-1) −v _(i))+K _(a) _(PV) ·a _(i-1) +K _(dsrc) ·a _(L)  (5)

As mentioned above, the C-ACC computer system 302 can implement a feed forward control algorithm to generate the acceleration control rate to control the host vehicle 106 based on the equations discussed above. Referring now to FIG. 7 a block diagram of an exemplary control system 700 of the C-ACC computer system 302 according to the control algorithm discussed above is shown. In FIG. 7, the control system 700 includes a feedforward control system 702 used as input to a C-ACC control system 704. The feedforward control system 702 receives as inputs an acceleration rate of the leading vehicle 108 a received using DSRC via the vehicle communication network 200, and an acceleration rate of the preceding vehicle 108 d received using the radar system 414. The inputs are modified by a dynamic gain, namely, the leading vehicle acceleration dynamic gain coefficient, to generate an acceleration reference signal a_(DSRC) _(ref) , which is received as input by the C-ACC control system 704. The C-ACC control system 704 determines the distance component and the velocity component as discussed above with equations (1)-(3) and can calculates an acceleration control rate using the input received from the feedforward control system 702.

II. Methods for C-ACC Control

Referring now to FIG. 8, a method 800 for controlling a host vehicle having a vehicle control system using vehicular communication will now be described according to an exemplary embodiment. FIG. 8 will also be described with reference to FIG. 1A, 1B and FIGS. 2-7. In one embodiment, the method 800 is for controlling the host vehicle 106 having a vehicle control system (e.g., the C-ACC computer system 302) that controls motion of the host vehicle 106 relative to the preceding vehicle 108 d. As shown in FIGS. 1A and 1B, the preceding vehicle 108 d is positioned immediately ahead of the host vehicle 106. At block 802, the method 800 includes receiving remote vehicle data about one or more remote vehicles. More specifically, in one embodiment, block 802 includes receiving V2V remote vehicle data 604 transmitted from one or more remote vehicles 108 to the host vehicle 106 via a vehicular communication network 200 and one or more communication links between the host vehicle 106 and each of the one or more remote vehicles 108. In some embodiments, V2V remote vehicle data 604 is received from one or more remote vehicles 108 within a predetermine distance (e.g., 300 m) from the host vehicle 106. As discussed above with FIGS. 1A, 1B, and 2, the host vehicle 106 is equipped with the V2V transceiver 110 that can communicate with other remote vehicles 108 operable for V2V communication on the roadway 102. For example, the V2V transceiver 110 can communicate with the remote vehicle 108 a via a V2V transceiver 112 a, the remote vehicle 108 b via a V2V transceiver 112 b, the remote vehicle 108 c via a V2V transceiver 112 c, and the remote vehicle 108 g via a V2V transceiver 112 d.

To facilitate communication, a communication link is established between the host vehicle 106 and the one or more remote vehicles 108 operable for V2V communication on the roadway 102. The communication link can be established between V2V transceivers. For example, the V2V transceiver 110 can continuously search for signals from other V2V transceivers, such as by emitting a periodic signal that searches for a reply. In other embodiments, the V2V transceiver 110 may emit periodic signals searching for a reply from an in-range V2V transceiver. If a V2V transceiver replies, then a communications link may be established. An exemplary communication link 203 between the host vehicle 106 and the remote vehicle 108 a is shown in FIG. 2.

As discussed above with FIG. 6, the host vehicle 106 can receive V2V remote vehicle data 604 from one or more of the remote vehicles 108 equipped for V2V communication. Thus, the V2V remote vehicle data 604, as discussed above with FIG. 6, can contains parameters of the remote vehicle 108 that transmitted the V2V remote vehicle data 604. In some embodiments, the V2V remote vehicle data 604 is contained in a message packet transmitted from one or more of the remote vehicles 108. For example, the message packet can be in a Basic Safety Message (BSM) format as defined for DSRC standards. Vehicles can periodically broadcast BSMs to announce their position, velocity, and other attributes to other vehicles. Information and data received by the host vehicle 106 can be saved to data logger system 402 and/or the data 310 and processed by the C-ACC computer system 302.

Referring again to block 802 of FIG. 8, in one embodiment, receiving remote vehicle data includes receiving remote vehicle data transmitted from a leading vehicle positioned ahead of the host vehicle and the preceding vehicle. For example, in FIGS. 1A and 1B, the host vehicle 106 can receive V2V remote vehicle data 604 from the leading vehicle 108 a. In one embodiment, the V2V remote vehicle data 604 includes an acceleration rate of the leading vehicle 108 a.

In another embodiment, receiving remote vehicle data at block 802 includes receiving remote vehicle data about remote vehicles and/or obstacles within a proximity of the host vehicle. For example, the remote vehicle data can include an acceleration rate of a preceding vehicle 108 d. In the embodiments discussed herein, the acceleration rate of the preceding vehicle 108 d can be detected by the host vehicle 106 using sensors on-board the host vehicle 106, for example, radar sensors. Thus, the remote vehicle data sensed by the host vehicle 106 can be sensed remote vehicle data 606. For example, with respect to the host vehicle 106 and FIG. 6, the host vehicle 106 detects sensed remote vehicle data 606 of the preceding vehicle 108 d using the radar system 414. Although the systems and methods discussed herein utilize acceleration data sensed by radar, it is understood that in other embodiments, the acceleration data can be received via the vehicle communication network 200 if the preceding vehicle 108 d is operably equipped for V2V communication with the host vehicle 106.

Referring again to FIG. 8, at block 804, the method 800 includes accessing host vehicle data from the host vehicle. As discussed above with FIG. 6, the host vehicle data 602 can be accessed from the vehicle sensor system 322 via the bus 330. In some embodiments, the host vehicle data 602 includes a velocity of the host vehicle 106 and an acceleration rate of the host vehicle 106, however it is understood that the host vehicle data 602 can include other types of data about the host vehicle 106.

At block 806, the method 800 includes calculating an acceleration control rate for the host vehicle. In one embodiment, the acceleration control rate is calculated by the processor 304 according to the C-ACC control model discussed above with equations (1)-(5). Block 806 will now be described in greater detail with respect to FIG. 9. FIG. 9 illustrates a method 900 for calculating an acceleration control rate accordingly to an exemplary embodiment. At block 902, the method 900 includes determining a relative headway distance between the host vehicle and the preceding vehicle with respect to a headway reference distance. For example, as discussed above with equation (1), the processor 304 can calculate a distance control component based on a relative distance between the host vehicle 106 and the preceding vehicle 108 d and a headway reference distance. The headway reference distance is a desired separation (e.g., distance) between the host vehicle 106 and the preceding vehicle 108 d. The headway reference distance can be predetermined and stored, for example at the memory 306.

At block 904, the method 900 includes determining a relative velocity between a velocity of the host vehicle and a velocity of the preceding vehicle. For example, as discussed above with equation (2), the processor 304 can calculate a velocity control component based on a velocity of the host vehicle 106 and a velocity of the preceding vehicle 108 d. At block 906, the method 900 includes determining an acceleration rate of the preceding vehicle. For example, as discussed above with block 802 of FIG. 8, the host vehicle 106 can determine the acceleration rate of the preceding vehicle 108 d using the radar system 414.

At block 908, the method 900 includes calculating an acceleration control rate for the host vehicle to maintain the headway reference distance between the host vehicle and the preceding vehicle. In particular, the acceleration control rate for the host vehicle is based on the relative headway distance, the relative velocity, the acceleration rate of the preceding vehicle, and the acceleration rate of the leading vehicle. Thus, in one embodiment, the processor 304 calculates the acceleration control rate for the host vehicle 106 according to equation (5) discussed above.

In one embodiment, calculating the acceleration control rate for the host vehicle can be based on a variable gain associated with the acceleration rate of the leading vehicle. For example, as shown in equations (4) and (5), K_(dsrc) is a leading vehicle acceleration dynamic gain coefficient. Accordingly, at block 910 the method 900 can include determining the variable gain. In one embodiment, the variable gain is based on a distance between the host vehicle and the leading vehicle. In some embodiments, the variable gain is based on a distance headway between the host vehicle and the leading vehicle and a time headway between the host vehicle and the leading vehicle. The distance headway, in some embodiments, is the relative headway distance.

The variable gain can be a function of a distance between the host vehicle and the leading vehicle. The variable gain can increase as the distance between the host vehicle and the leading vehicle decreases. As an illustrative example with reference to FIG. 1B, according to one embodiment, a variable gain where the remote vehicle 108 a is the leading vehicle would be less than a variable gain where the remote vehicle 108 c is the leading vehicle based on the distance to the host vehicle 106. In other embodiments, the variable gain can be a function of a distance headway between the host vehicle and the leading vehicle and/or a time headway between the host vehicle and the leading vehicle. The variable gain can increase as the distance headway and/or the time headway increases. The variable gain determined at block 910 can be used to modify the acceleration rate of the host vehicle by the variable gain at block 912. Further, similar to block 806 of FIG. 8, the acceleration control rate can be calculated at block 908.

Referring back to FIG. 8, the method 800 includes at block 808 controlling a vehicle control system of the host vehicle. In one embodiment, block 808 can include controlling the vehicle control system of the host vehicle according to the acceleration control rate. For example, the acceleration control rate can be output by the C-ACC control system 300 to the ECU 320 in order to control one or more vehicle systems according to the acceleration control rate. For example, the C-ACC control system 300 via the ECU 320 can begin to automatically decelerate or accelerate the host vehicle 106 based on the acceleration control rate by controlling the brake actuator 608 and/or the throttle actuator 610. Alternatively or simultaneously, with acceleration and/or braking of the host vehicle 106, controlling the vehicle control system of the host vehicle at block 808 can include controlling the vehicle interface system 328. For example, the C-ACC control system 300 can generate information, suggestions, warnings, and/or alerts and provide the same to a driver on display device 510. In other embodiments, tactile feedback can be provided according to the acceleration control rate. For example, the AFP of the acceleration pedal 514 can provide feedback with active force as the driver pushes the acceleration pedal 514 to encourage acceleration and/or deceleration based on the acceleration control rate.

As mentioned above with method 800, the acceleration control rate is based in part on the acceleration rate of a leading vehicle. Appropriate control of the host vehicle can depend on which remote vehicle is identified as the leading vehicle. As will now be described with reference to FIG. 10, in some embodiments, the leading vehicle is selected based on the remote vehicle data, specifically, the V2V remote vehicle data 604 transmitted between the host vehicle 106 and one or more of the remote vehicles 108. FIG. 10 illustrates a method 1000 for selecting a leading vehicle from a plurality of remote vehicles according to an exemplary embodiment. At block 1002, the method 1000 includes receiving remote vehicle data from a plurality of remote vehicles. For example, as discussed above with block 802, the host vehicle 106 is equipped with the V2V transceiver 110 that can communicate with other vehicles operable for V2V communication on the roadway 102.

At block 1004, the method 1000 includes selecting the leading vehicle from the plurality of remote vehicles by selecting the leading vehicle based on the remote vehicle data received at block 1002. In one embodiment, selecting the leading vehicle from the plurality of remote vehicles includes selecting the remote vehicle that has the greatest impact on the operation of the host vehicle and/or the travel path of the host vehicle. The processor 304 can determine which remote vehicle of the plurality of remote vehicles has the greatest impact on the host vehicle based on the V2V remote vehicle data 604 transmitted from the plurality of remote vehicles 108 and host vehicle data 602 about the host vehicle 106. For example, determining which remote vehicle 108 has the greatest impact on the host vehicle 106 can be based on speed, distance, braking, among others.

In one embodiment, selecting the leading vehicle from the plurality of remote vehicles includes selecting the leading vehicle from the plurality of remote vehicles that is within a predetermined headway time threshold from the host vehicle. As an illustrative example with respect to FIG. 1B, the C-ACC control system 300 can set a predetermined headway time threshold, stored for example at the memory 306. In one embodiment, the predetermined headway time threshold is five (5) seconds from the host vehicle 106. Accordingly, in one embodiment, the C-ACC control system 300 selects a leading vehicle from the plurality of remote vehicles in vehicular communication with the host vehicle 106 (e.g., the remote vehicle 108 a, the 108 b, the 108 c) that is within a five second headway time threshold from the host vehicle 106. As an illustrative example, the remote vehicle 108 c has a three second headway time from the host vehicle 106, the remote vehicle 108 b has a five second headway time from the host vehicle 106, and the remote vehicle 108 a has a seven second headway time from the host vehicle 106. According to this example, the leading vehicle would be selected as either the remote vehicle 108 c or the remote vehicle 108 b, which are both within a five second headway time from the host vehicle 106.

In another embodiment, selecting the leading vehicle from the plurality of remote vehicles includes selecting the leading vehicle from the plurality of remote vehicles based on a deceleration rate of the plurality of remote vehicles. As discussed herein, the plurality of remote vehicles 108 in vehicular communication with the host vehicle 106 can transmit V2V remote vehicle data 604 including speed data, braking data, acceleration data, and deceleration data. Thus, in one embodiment, the leading vehicle is selected as the remote vehicle 108 having the greatest deceleration rate of the plurality of remote vehicles 108.

In another embodiment, selecting the leading vehicle from the plurality of remote vehicles includes selecting the leading vehicle from the plurality of remote vehicles based on a speed of the plurality of remote vehicles. As discussed herein, the plurality of remote vehicles 108 in vehicular communication with the host vehicle 106 can transmit V2V remote vehicle data 604 including speed data. Thus, in one embodiment, the leading vehicle is selected as the remote vehicle having the lowest speed of the plurality of remote vehicles. As an illustrative example with respect to FIG. 1B, the remote vehicle 108 c has a speed of 35 mph, the remote vehicle 108 b has a speed of 25 mph, and the remote vehicle 108 a has a speed of 15 mph. In this example, the remote vehicle 108 a would be selected as the leading vehicle based on having the lowest speed.

In another embodiment, selecting the leading vehicle from the plurality of remote vehicles includes selecting the leading vehicle from the plurality of remote vehicles based on a deceleration rate of the plurality of remote vehicles and a speed of the plurality of remote vehicles. In further embodiments, the leading vehicle is the remote vehicle having the lowest speed of the plurality of remote vehicles and that is within a predetermined headway time threshold from the host vehicle. In this embodiment and with reference to the examples discussed above, the remote vehicle 108 b would be selected as the leading vehicle because the remote vehicle 108 b is within a predetermined headway time threshold of five seconds from the host vehicle 106 and has the lowest speed out of the remote vehicles 108 that are within the predetermined headway time threshold.

Upon selecting the leading vehicle, at block 1006, the method 1000 includes receiving remote vehicle data from the leading vehicle, for example, an acceleration rate, as described above with block 802. It is understood that the acceleration rate can also be received at block 1002. At block 1008, the method 1000 can return to block 802 of method 800.

The V2V remote vehicle data 604 received from the leading vehicle is critical in providing an accurate response by the host vehicle 106. In some embodiments, the V2V remote vehicle data 604 could be skewed or unavailable due to vehicle communication network 200 issues or issues with the communication link between the host vehicle 106 and each of the remote vehicles 108. Thus, in some embodiments, selecting a leading vehicle at block 1004 and/or receiving V2V remote vehicle data 604 from the leading vehicle at block 1006 can include methods for monitoring wireless communication connectivity and quality. Referring now to FIG. 11, a method 1100 for monitoring communication between the host vehicle and the leading vehicle will be discussed in detail.

At block 1102, the method 1100 includes monitoring a communication link between the host vehicle and the leading vehicle. As discussed above with block 802 of FIG. 8, to facilitate communication, a communication link is established between the host vehicle 106 and the one or more remote vehicles 108 operable for V2V communication on the roadway 102. For example, in FIG. 2, the communication link 203 is shown between the host vehicle 106 and the remote vehicle 108 a. The communication link 203 is monitored for packet loss and communication link signal strength. At block 1104, the method 1100 includes determining if a message packet has been lost. DSRC message packets are periodically broadcast to the host vehicle 106 from the leading vehicle 108 a. In one embodiment, message packets are sent ten times per second. As the host vehicle 106 receives the message packets from the leading vehicle 108 a, the host vehicle 106 can count and store the message packets via the data logger system 402 and/or the data 310 and processed by the C-ACC computer system 302. By tracking the message packets received, the host vehicle 106 at block 1104 can identify if a packet has been lost. In some embodiments, the host vehicle 106 can determine a packet loss error rate and compare the packet loss error rate to a predetermine threshold. In other embodiments, at block 1104, it is determined if the signal strength of the communication link 203 between the host vehicle 106 and the leading vehicle 108 a is below a predetermined threshold.

If the determination at block 1104 is YES, the method 1100 proceeds to block 1106. At block 1106, the remote vehicle data from the message packet previously transmitted by the leading vehicle 108 a is utilized, for example, for calculating an acceleration control rate at block 806 of FIG. 8. A counter i stored by the memory 306 indicating the number of packet losses is also incremented at block 1106.

At block 1108, the counter i is compared to a predetermined threshold N. If the number of lost packets i exceeds the predetermined threshold N, the method 1100 proceeds to block 1110. At block 1110, the method 1100 includes selecting a new leading vehicle. For example, in one embodiment, selecting a new leading vehicle from the plurality of remote vehicles includes selecting the new leading vehicle from the plurality of remote vehicles that is in closest proximity to the current leading vehicle. Referring to FIG. 1B, as an illustrative example, the remote vehicle 108 a is the current leading vehicle. Selecting the new leading vehicle can be based on proximity to the current leading vehicle, namely, the remote vehicle 108 a. Thus, in FIG. 1B, the processor 304 can select the remote vehicle 108 b as the new leading vehicle because the remote vehicle 108 b is the remote vehicle in closest proximity to the remote vehicle 108 a. It is understood that in some embodiments, selecting the new leading vehicle can based on other factors (e.g., deceleration rate, speed) as described above with block 1004 of FIG. 10.

At block 1112, the method 1100 includes monitoring the communication link between the host vehicle and the new leading vehicle. The communication link between the host vehicle and the new leading vehicle is monitored for packet loss and signal strength, similar to block 1102. Accordingly at block 1114, it is determined if a message packet has been lost. In other embodiments, at block 1114 it is determined if the signal strength of the communication link between the host vehicle and the new leading vehicle is below a predetermined threshold. If the determination at block 1114 is YES, the method 1100 proceeds to block 1116. At block 1116, the processor 304 discards the V2V remote vehicle data 604 received from the leading vehicle (e.g., the new leading vehicle) for purposes of controlling a vehicle control system. For example, the processor 304 can calculate the acceleration control rate based only on host vehicle data 602 and sensed remote vehicle data 606 obtained by on-board sensors (e.g., using the radar system 414). Further, in some embodiments at block 1116, the communication link between the host vehicle 106 and the new leading vehicle 108 b can be terminated. Controlling the quality of data as described with FIG. 11 mitigates the effects of skewed or unavailable V2V remote vehicle data 604 on the vehicle control methods described herein.

III. Methods for Hazard Detection

As mentioned above, the systems and methods described herein are generally directed to controlling a vehicle using a vehicle communication network that can include multiple vehicles and infrastructures. In some embodiments, systems and methods discussed herein detect hazards that may pose a threat to the operation and/or the travel path of a host vehicle based in part on vehicular communication with one or more of remote vehicles. Thus, the vehicle communication network 200 and the systems described in FIGS. 2-7 can be used to facilitate hazard detection and vehicle control using V2V communication by providing lane level hazard predictions in real-time.

FIG. 12 illustrates an exemplary traffic scenario 1200 that will be used to describe some of the systems and methods for hazard detection discussed herein. The traffic scenario 1200 is a simplified version of the traffic scenario 100 of FIG. 1. In FIG. 12, the roadway 1202 has a first lane 1204 a, a second lane 1204 b, and a third lane 1204 c. It is understood that the roadway 1202 can have various configurations not shown in FIG. 12, and can have any number of lanes. The roadway 1202 includes a host vehicle 1206 and remote vehicles. For simplicity, the remote vehicles will be generally referred to herein as remote vehicles 1208. Further, for simplicity, the host vehicle 1206 and the remote vehicles 1208 all include V2V transceivers, although they are not individually numbered in FIG. 12. It is understood that the host vehicle 1206 and the remote vehicles 1208 can have the same or similar components and functions as the host vehicle 106 and the remote vehicles 108 discussed above with FIGS. 1A, 1B, 2-7. For example, the host vehicle 1206 can transmit, receive, and/or exchange communications including data, messages, images, and/or other information with other vehicles, user, or infrastructures, using DSRC and the vehicle communication network 200 of FIG. 2.

By using vehicle information from the remote vehicles 1208 surrounding the host vehicle 1206 via DSRC, the host vehicle 1206 gains situational awareness of upcoming hazards and/or can provide better control of vehicle systems in anticipation of upcoming hazards or lane level issues. For example, acceleration and deceleration parameters (e.g., C-ACC computer system 302) can be controlled to smooth braking and eliminate hard braking phantom traffic jams based on upcoming hazards or lane level issues. Accordingly, the dynamics (e.g., motion) of the host vehicle 1206 and/or an interface of the host vehicle 1206 (e.g., the vehicle interface system 328) can be controlled based, in part, on data from DSRC communication with the remote vehicles 1208. Thus, information propagated by the remote vehicles 1208 ahead of and/or behind the host vehicle 1206 provides valuable information to the host vehicle 1206 that can increase safety and provide a smoother driving experience. Detailed systems, methods, and illustrative examples of hazard detection and vehicle control will now be discussed in more detail.

FIG. 13 illustrates a method 1300 for controlling a vehicle control system of a host vehicle using hazard detection. At block 1302, the method 1300 includes receiving remote vehicle data. For example, as discussed above with block 802 of FIG. 8, the host vehicle 1206 is equipped with a V2V transceiver that can communicate with other vehicles operable for V2V communication on the roadway 1202. Thus, the host vehicle 1206 can receive V2V remote vehicle data 604 from remote vehicles 1208 that are equipped for DSRC communication. At block 1304, the method 1300 includes accessing host vehicle data. For example, as discussed with block 804 of FIG. 8 and with FIG. 6, the host vehicle data 602 can be accessed from the vehicle sensor system 322 via the bus 330. At block 1306, the method 1300 includes detecting a hazard based on the remote vehicle data and the host vehicle data. In some embodiments, detecting the hazard includes identifying for each remote vehicle 1208 a longitudinal position (e.g., ahead or behind) with respect to the host vehicle 1206, a lane the remote vehicle 1208 is travelling in with respect to the host vehicle 1206, and for remote vehicles 1208 not in the same lane as the host vehicle 1206, a lateral direction (e.g., left, right) with respect to the host vehicle 1206. Accordingly, in one embodiment, detecting a hazard at block 1306 can include at block 1308, classifying one or more of the remote vehicles 1208 by lane and/or position relative to the host vehicle 1206. Block 1308 will be discussed in further detail herein with respect to FIGS. 14A and 14B.

In FIG. 13 at block 1310, the method 1300 can optionally include calculating an acceleration control rate based on the hazard. In one embodiment, the processor calculates the acceleration control rate for the host vehicle 1206 according to the control model discussed above with respect to equations (1)-(5). For example, in one embodiment, detecting the hazard at block 1306 can include selecting a leading vehicle as described with block 1004 of FIG. 10 in accordance with the hazard. For example, as will be discussed herein, in one embodiment, a remote vehicle having the greatest deceleration rate and/or the lowest (e.g., slowest) speed in a lane can be identified as a hazard. This remote vehicle could be selected as a leading vehicle having the greatest impact on the operation and/or travel path of the host vehicle 1206. Thus, the acceleration rate of this remote vehicle can be used to calculate the acceleration control rate at block 1310. At block 1312, the method 1300 can include controlling a vehicle control system based on the hazard and/or according to the acceleration control rate, similar to block 808 of FIG. 8.

As mentioned above, in some embodiments discussed herein, hazard detection includes identifying for each remote vehicle a longitudinal position (e.g., ahead or behind) with respect to the host vehicle, a lane the remote vehicle is travelling in with respect to the host vehicle, and for remote vehicles not in the same lane as the host vehicle, a lateral direction (e.g., left, right) with respect to the host vehicle. Generally, V2V remote vehicle data 604 received at block 1302 of FIG. 12 is parsed and a position of a remote vehicle and previous positions of the remote vehicle are compared to a position of the host vehicle. Methods for classifying the remote vehicles 1208 by lane and position with respect to the host vehicle 1206 will now be discussed in more detail with reference to FIG. 14A.

FIG. 14A illustrates a method 1400 for classifying remote vehicles according to an exemplary embodiment. In particular, the method 1400 provides for lane level classification of remote vehicles relative to the host vehicle. For each remote vehicle 1208 travelling in the same direction as the host vehicle 1206 at block 1402, the method 1400 proceeds to block 1404, where it is determined if the remote vehicle is positioned ahead of the host vehicle 1206. More specifically, at block 1404, the processor 304 determines a longitudinal position (e.g., ahead or behind) with respect to the host vehicle 1206. In one embodiment, the processor 304 can use the position data received from the remote vehicles 1208 to determine a longitudinal position. For example, if a remote vehicle azimuth degree is greater than −90 degrees and less than 90 degrees, the remote vehicle is determined to be ahead of the host vehicle 1206. As an illustrative example in FIG. 12, the remote vehicles 1208 a-c, 1208 e-f, and 1208 h-j are ahead of the host vehicle 1206, while the remote vehicles 1208 d, 1208 g, and 1208 k are behind the host vehicle 1206. If the remote vehicle 1208 is ahead of the host vehicle 1206, the method 1400 proceeds to block 1406. At block 1406, the method 1400 includes calculating and/or predicting a predicted lateral offset between the remote vehicle 1208 and the host vehicle 1206. In some embodiments, block 1406 also includes calculating and/or predicting a predicted longitudinal offset between the remote vehicle 1208 and the host vehicle 1206.

Block 1406 will now be described in more detail with FIG. 14B, which is a schematic diagram 1412 of a remote vehicle 1414 ahead of a host vehicle 1416 and travelling in the same direction on a curved roadway 1420. The remote vehicle 1414 and the host vehicle 1416 are shown within an x-axis and y-axis coordinate frame with a reference point (0, VCenterY). In one embodiment, the lateral offset (Predicted LatOffset) and the longitudinal offset (Predicted LongOffset) are predicted using a current position of the host vehicle 1416 (HVvehiclePos(0)) and a remote vehicle path trail 1418 of the remote vehicle 1414. The remote vehicle path trail 1418 is comprised of path history points, which are shown in FIG. 14B as circles along the remote vehicle path trail 1418. The past history points can be remote vehicle data, either received by V2V communication or sensed by the host vehicle 1416, and stored by the host vehicle 1416.

The remote vehicle path trail 1418 is defined by a line segment that joins a current position of the remote vehicle RVPos(0) to consecutive path history points of the remote vehicle RVPos(−1) to remote RVPos(−N), where N is the total number of path history points. In one embodiment, to calculate the longitudinal offset (Predicted LongOffset), a series of longitudinal offset points are determined based on individual line segment distances connecting the current position of the host vehicle 1416 vehiclePos(0) to the closest path history points along the remote vehicle path trail 1418 along the y-axis. If the roadway is curved, as shown in FIG. 14B, longitudinal offset (Predicted LongOffset) can be based on a predicted path 1420 (e.g., arc, radius of the predicted path 1420) and a heading of the host vehicle 1416.

To determine a predicted lateral offset (Predicted LatOffset), in one embodiment, a series of lateral offset points are calculated along the remote vehicle path trail 1418 based on a perpendicular distance between the current position of the host vehicle 1416 and a closest point on the remote vehicle path trail 1418 from the current position of the host vehicle 1416 along the x-axis. For a curved roadway as shown in FIG. 14B, a predicted lateral offset (Predicted LatOffset) can be based on a perpendicular distance between a current position of the remote vehicle 1414 (RVPOS(0)) and a projected arc length of the host vehicle 1416. Additional lateral offset points can be based on the arc length of the remote vehicle path trail 1418.

Based on the calculated lateral offset points, a predicted lateral offset can be determined. For example, in one embodiment, the predicted lateral offset is determined by averaging each lateral offset point. In another embodiment, calculating the predicted lateral offset considers weighted factors. More specifically, in one embodiment, calculating the predicted lateral offset includes calculating the predicted lateral offset based on one or more perpendicular distances between the current position of the host vehicle and one or more path history points of the remote vehicle, and a distance between consecutive path history points of the remote vehicle and a current position of the remote vehicle. Referring now to FIG. 14C, a detailed method 1422 for predicting lateral offset according to an exemplary embodiment is shown. At block 1424, configuration parameters are read, for example, from a look-up table stored at the data 310. At block 1426, it is determined whether weighting is enabled based on the configuration parameters from block 1424. If weighting is not enabled, the method proceeds to block 1428 and the predicted lateral offset is calculated using averaging as discussed above, without weighting. For example, the predicted lateral offset can be determined by calculating an average of multiple lateral offset points.

If weighting is enabled at block 1426, at block 1430 it is determined if inverse distance weighting (IDW) is enabled based on the configuration parameters from block 1424. IDW provides more significance to path history points closer in two dimensional Euclidean distance to the current position of the remote vehicle. In one embodiment, the weight value can decrease as the distance of the path history points increase from the current position of the remote vehicle. If IDW is not enabled, at block 1432, the predicated lateral offset is calculated using an average with a default weight factor. For example, the default weight factor can be expressed mathematically as:

$\begin{matrix} {w_{i} = \frac{1}{i}} & (6) \end{matrix}$

If IDW is enabled, the method 1422 proceeds to block 1434 where the two dimensional Euclidean distance between consecutive path history points (e.g., consecutive path history points on the remote vehicle path trail 1418) is calculated according to the following function:

di=√{square root over ((x _(c) −x ₁)²+(y _(c) −y ₁)²)}+Σ_(n=1) ^(i+1)√{square root over ((x _(n) −x _(n-1))²+(y _(n) −y _(n-1))²)}  (7)

where x_(c) is a current x-axis position of the remote vehicle, y_(c) is a current y-axis position of the remote vehicles, x₁ is the remote vehicle most recent path history x-axis position (RVPosX(−1)), y₁ is the remote vehicle most recent path history y-axis position (RVPosY(−1)), x_(n) is the remote vehicle n^(th) path history x-axis position, and y_(n) is the remote vehicle n^(th) path history y-axis position. The two-dimensional Euclidean distance considers the distance between consecutive path history points of the remote vehicle 1414 and the current position of the remote vehicle 1414. Referring again to FIG. 14C, at block 1436, a weight factor is calculated for the IDW function based on the distance between consecutive path history points as determined at block 1434. In one embodiment, the weight factor can be expressed as:

$\begin{matrix} {w_{i} = \frac{1}{d_{i}^{p}}} & (8) \end{matrix}$

where p is a power factor used to control weighting memory. Thus, the weight factor in equation (8) is dependent on the distance between consecutive path history points of the remote vehicle 1414 and the current position of the remote vehicle 1414. For example, in one embodiment, the weight value can decrease as the distance of the path history points increase from the current position of the remote vehicle. Accordingly, at block 1438, the weight factor is applied to calculate the predicted lateral offset. This can be expressed mathematically as:

$\begin{matrix} {{LatOffsetPredicted} = \frac{{LatOffset}_{1} + {\sum\limits_{k = 3}^{M + 2}{w_{k - 2} \cdot {Latoffset}_{k}}}}{1 + {\sum\limits_{i = 1}^{M}w_{i}}}} & (9) \end{matrix}$

At block 1440, the predicted lateral offset is used to classify the lane and position of the remote vehicle and the process returns to block 1408 of FIG. 14A. Referring again to FIG. 14A, at block 1408, the method 1400 includes determining and/or assigning a lane to the remote vehicle based on the predicted lateral offset. The lane is determined and/or assigned relative to the host vehicle and can include a directional component with respect to the host vehicle and/or the host vehicle lane. In one embodiment, the remote vehicle lane can be determined based on the predicted lateral offset with respect to the lane widths. Data about the lane widths of the roadway 1202 can be obtained, for example, from map component data 314. The classification can include a lane identifier (e.g., adjacent lane, same lane), a direction of the lane relative to the host vehicle and/or the host vehicle lane (e.g., right, left), and a distance associated with the direction of the lane relative to the host vehicle and/or the host vehicle lane (e.g., far left, far right). The lane assignments and/or lane classifications of the remote vehicle can include, but are not limited to, the same lane as the host vehicle, in a right adjacent lane with respect to the host vehicle, in a right far lane with respect to the host vehicle, in the left adjacent lane with respect to the host vehicle, and in a left far lane with respect to the host vehicle. For example, in FIG. 12, the remote vehicle 1208 e is in the same lane (i.e., the second lane 1204 b) as the host vehicle 1206, the remote vehicle 1208 c is in the left adjacent lane (i.e., the first lane 1204 a), and the remote vehicle 1208 j is in the right adjacent lane (i.e., the third lane 1204 c). It is understood that other types (e.g., discrete values, numerical values, continuous values) of lane classifications can be implemented.

At block 1410, the method 1400 includes classifying the remote vehicle at a lane level relative to the host vehicle. This can be based on the remote vehicle lane determined at block 1408. The classification can include a lane identifier (e.g., adjacent lane, same lane), a direction of the lane relative to the host vehicle and/or the host vehicle lane (e.g., right, left), and a longitudinal position relative to the host vehicle (e.g., ahead, behind). For example, a remote vehicle in the same lane as the host vehicle is classified as in the same lane and ahead of the host vehicle. A remote vehicle in the left adjacent lane is classified in the left adjacent lane and ahead of the host vehicle. A remote vehicle in the right adjacent lane is classified in the right adjacent lane and ahead of the host vehicle. As an illustrative example with respect to FIG. 12, the remote vehicle 1208 c can be classified as in the left adjacent lane 1204 a and ahead of the host vehicle 1206. It is understood that other types (e.g., discrete values, numerical values, continuous values) of remote vehicle classifications can be implemented. As will be discussed herein, these classifications will be used to facilitate determination of lane level hazards.

Referring now to FIG. 15 an exemplary method 1500 for hazard detection using vehicle communication is shown according to another exemplary embodiment. In one embodiment, the method 1500 can be used for lane level speed hazard detection. Traffic flow condition monitoring helps avoid unnecessary travel delays and stress to drivers, especially in congested traffic scenarios. Using DSRC communication as described herein, lane level speed monitoring with V2V remote vehicle data can help provide a driver of a host vehicle with lane level traffic flow information and/or can be used to control the host vehicle to anticipate and avoid lane level traffic flow issues. FIG. 15 will be described in reference to FIGS. 2-7, 12 and 13. At block 1502, the method 1500 includes receiving remote vehicle data as described above with block 1302 of FIG. 13. Further, at block 1504, the method 1500 includes accessing host vehicle data as discussed above with block 1304 of FIG. 13. At block 1506, the method 1500 includes classifying the lane and position of each remote vehicle with respect to the host vehicle as discussed above with block 1308 of FIG. 13. At block 1508, the method 1500 includes calculating lane level traffic flow data.

In one embodiment, calculating lane level traffic flow data at block 1508 can include determining a traffic flow speed for each lane by averaging the speed of each remote vehicle in each lane ahead of the host vehicle. As an illustrative example, with respect to FIG. 12, a traffic flow speed for the first lane 1204 a can be determined by averaging the speed data (e.g., received at block 1502) for remote vehicles 1208 a, 1208 b, and 1208 c, which are in the first lane 1204 a and positioned ahead of the host vehicle 1206. Traffic flow speed for the lanes 1204 b and 1204 c can similarly be determined.

In another embodiment, calculating lane level traffic flow data at block 1508 can include identifying a remote vehicle in each lane having the lowest (e.g., minimum) speed among all remote vehicles in the respective lane. For example, the processor 304 can determine the speed of each remote vehicle ahead of the host vehicle 1206 based on the remote vehicle data received at block 1502. For each lane, the processor 304 determines which remote vehicle has the lowest speed. As an illustrative example, in the first lane 1204 a, the remote vehicle 1208 a may have a speed of 45 mph, the remote vehicle 1208 b may have a speed of 30 mph, and the remote vehicle 1208 c may have a speed of 35 mph. In this example, the processor 304 identifies the remote vehicle 1208 b has having the lowest speed in the first lane 1204 a. Remote vehicles with minimum speed for the lanes 1204 b and 1204 c can similarly be determined.

In some embodiments the method 1500 can optionally include at block 1510 determining if a traffic flow hazard is detected based on the traffic flow data. A traffic flow hazard can affect the operation and/or the travel path of the host vehicle 1206. For example, in one embodiment, if a remote vehicle in the same lane as the host vehicle is identified as having a minimum speed that is less than a predetermined threshold, the processor 304 can determined that a hazard exists. In some embodiments, if the determination at block 1510 is NO, the method can return to block 1508. Otherwise, the method 1500 can optionally include at block 1512, calculating an acceleration control rate of the host vehicle. The acceleration control rate can be based on the traffic flow information. For example, the acceleration control rate can be determined based on the control model discussed above with equations (1)-(5). In one embodiment, the leading vehicle can be selected as described at block 1004 of FIG. 10 based on the remote vehicle in the same lane as the host vehicle identified as having the lowest speed and/or the greatest deceleration rate.

At block 1514, the method 1500 includes controlling a vehicle control system based on the traffic flow data and/or the traffic flow hazard. For example, the processor 304 can generate visual feedback on the display 510 illustrating the traffic flow in each lane and/or identifying a remote vehicle as a traffic flow hazard. For example, a graphic showing a remote vehicle in the same lane as the host vehicle identified as having the lowest speed can be highlighted to warn the driver about the potential traffic flow hazard. It is understood that other types of feedback based on the traffic flow data can be provided via the vehicle interface system 328. In other embodiments as described above with block 808 of FIG. 8, one or more vehicle systems 404 can be controlled based on the acceleration control rate and/or the hazard. For example, the acceleration control rate can be output by the C-ACC control system 300 to the ECU 320 in order to control one or more vehicle systems according to the acceleration control rate.

Another method for hazard detection using vehicle communication will now be described with reference to FIG. 16. Specifically, FIG. 16 shows a method 1600 for hazard detection based on identifying remote vehicle lane changes according to an exemplary embodiment. FIG. 16 will be described with reference to FIGS. 2-7 and 13. At block 1602, the method 1600 includes receiving remote vehicle data as described above with block 1302 of FIG. 13. Further, at block 1604, the method 1600 includes accessing host vehicle data as discussed above with block 1304 of FIG. 13. At block 1606, the method 1500 includes classifying the lane and position of each remote vehicle with respect to the host vehicle as discussed above with block 1308 of FIG. 13 and with FIGS. 14A, 14B, and 14C. In some embodiments, at block 1606, remote vehicles travelling ahead of the host vehicle and in the same lane as the host vehicle are identified (e.g., as classified in FIG. 14A). An illustrative example will be described with respect to FIG. 17, which shows a traffic scenario 1700 similar to the traffic scenario 1200 of FIG. 12. For simplicity, like numerals represent like elements. In FIG. 17, remote vehicles 1208 c, 1208 d, and 1208 e are travelling ahead of the host vehicle 1206 in the same lane as the host vehicle 1206.

Referring again to FIG. 16, at block 1608 the method 1600 includes identifying lane changes of the remote vehicles ahead of the host vehicle. In one embodiment, the processor 304 analyzes the trajectory (e.g., current position and previous position) of each remote vehicle 1208 relative to the host vehicle 1206 trajectory to determine if one or more of the remote vehicles 1208 have changed lanes within a predetermined time window. The processor 304 can predict ongoing lane changes by analyzing a turn signal status of each remote vehicle 1208, relative lateral distance between the remote vehicle 1208 and the host vehicle 1206, lateral acceleration, yaw rate, and heading. In another embodiment, for each remote vehicle 1208 travelling ahead of the host vehicle in the same lane as the host vehicle 1206, it is determined if a turn signal of the remote vehicle 1208 is activated to determine a number of lane changes.

At block 1610, it is determined if the number of active turn signals and/or the number of identified lane changes exceeds a predetermined threshold. If the determination at block 1610 is NO, a hazard is not detected and the method 1600 can proceed back to block 1602. Otherwise, at block 1612, it is determined if the speed of the remote vehicles 108 is less than a predetermined speed threshold. This decrease in speed can indicate that one or more of the remote vehicles 1208 are slowing down in a similar manner prior to changing lanes. If the determination at block 1612 is NO, a hazard is not detected and the method 1600 can proceed back to block 1602. Otherwise, at block 1614, the method 1600 can optionally include calculating an acceleration control rate. In one embodiment, the processor 304 calculates the acceleration control rate for the host vehicle 1206 according to the control model discussed above with respect to equations (1)-(5). Further, at block 1616, the method 1600 can include controlling a vehicle control system of the host vehicle based on the lane changes and/or the acceleration control rate. For example, the processor 304 can generate visual feedback on the display 510 illustrating the hazard and/or providing a notification about the hazard. For example, the processor 304 can generate a graphic that illustrates a potential hazard in the same lane as the host vehicle. The lane and/or hazard can be highlighted to warn the driver about the potential traffic flow hazard. It is understood that other types of feedback based on the traffic flow data can be provided via the vehicle interface system 328. In other embodiments as described above with block 808 of FIG. 8, one or more vehicle systems 404 can be controlled based on the acceleration control rate and/or the hazard. For example, the acceleration control rate can be output by the C-ACC control system 300 to the ECU 320 in order to control one or more vehicle systems according to the acceleration control rate.

IV. Methods for Merge Assist

As mentioned above, the systems and methods described herein are generally directed to controlling a vehicle using a vehicle communication network that can include multiple vehicles and infrastructures. In some embodiments, cooperative merge assistance can be provided using a vehicle communication network between vehicles equipped for V2V (e.g., DSRC) communication. For example, DSRC communication can be used to assist a host vehicle merging into a lane with congested traffic. FIG. 18 illustrates an exemplary traffic scenario 1800 that will be used to describe system and methods for cooperative merge assistance. In FIG. 18, the traffic scenario 1800 involves one or more vehicles on a roadway 1802 having a first lane 1804 a and a second lane 1804 b. It is understood that the roadway 1802 can have various configurations not shown in FIG. 18, and can have any number of lanes.

The traffic scenario 1800 includes a host vehicle 1806 travelling in lane 1804 b with an intent to merge into lane 1804 a. In some embodiments, the lane 1804 a will be referred to as a merging lane. Remote vehicles are travelling in lane 1804 a. The remote vehicles will be generally referred to by element number 1808. However, more specifically, the remote vehicles 1808 can be referred to as a remote vehicle 1808 a, a remote vehicle 1808 b, and a remote vehicle 1808 c. In some embodiments, the remote vehicles 1808 can be referred to as a plurality of remote vehicles 1808. Similar to the host vehicle 106 discussed with FIGS. 1A, 1B, and 2-7, the host vehicle 1806 can transmit, receive, and/or exchange communications including data, messages, images, and/or other information with other vehicles, user, or infrastructures, using DSRC. For simplicity, in FIG. 18, the host vehicle 1806 and the remote vehicles 1808 all include V2V transceivers. It is understood that the host vehicle 1806 and the remote vehicles 1808 can include the same or similar components and functions as discussed above with the host vehicle 106 and the remote vehicles 108. Throughout this description of cooperative merge assistance, reference will be made to the components of FIGS. 2-7.

The host vehicle 1806 can include a plurality of midrange radars or other sensing devices that can be part of the radar system 414. In FIG. 18, the plurality of midrange radars may include a front left midrange radar 1810 located at a front left corner area of the host vehicle 1806, a front right midrange radar 1812 located at a front right corner area of the host vehicle 1806, a rear left midrange radar 1814 located at a rear left corner area of the host vehicle 1806, and a rear right midrange radar 1816 located at a rear right corner area of the host vehicle 1806. However, in other embodiments, the plurality of midrange radars can be placed in any suitable position on the host vehicle 1806.

Referring now to FIG. 19 a process flow diagram of a method 1900 for providing cooperative merge assistance using a vehicle communication network according to an exemplary embodiment is shown. At block 1902, the method 1900 includes activating a merge assist system (e.g., the vehicle computer system 302). For example, user input (e.g., from a driver) can be received from the input portion of the vehicle interface system 328 to activate a merge assist mode. At block 1904, the method 1900 includes receiving remote vehicle data about one or more remote vehicles, as discussed above with block 802 of FIG. 8. The remote vehicle data can include V2V remote vehicle data 604 from the remote vehicles 1808 and/or sensed remote vehicle data 606 about the remote vehicles 1808. In one embodiment, the processor 304 can receive speed data transmitted from the one or more remote vehicles 1808 travelling in a merge lane (e.g., the lane 1804 a) via the vehicle communication network 200. For example, the processor 304 can receive speed data transmitted from the one or more remote vehicles 1808 via the vehicle communication network 200.

Additionally, in some embodiments, position data of the one or more remote vehicles 1808 can be received from a sensor system of the host vehicle 1806 that monitors an area around the host vehicle 1806. For example, the processor 304 can receive position data about one or more of the remote vehicles 1808 via the plurality of midrange sensors (e.g., sensed remote vehicle data 606 from the radar system 414) as discussed above with FIG. 18. At block 1906, the method 1900 includes accessing host vehicle data from the host vehicle. For example, as discussed above with block 804 of FIG. 8, the host vehicle data 602 can be accessed from the vehicle sensor system 322 via the bus 330.

At block 1908, the method 1900 can optionally include calculating an acceleration control rate. In some embodiments, calculating the acceleration control rate can be calculated with some or all of the components shown in equations (1)-(5) and discussed with block 806 of FIG. 8. More specifically, the processor 304 calculates the acceleration control rate for the host vehicle 1808 according to the control model discussed above in equations (1)-(5). In one embodiment, which will be discussed herein, the acceleration control rate of the host vehicle 1806 can be based on an average of the speed data received at block 1904. At block 1910, the method 1900 can include controlling a vehicle system of the host vehicle, similar to block 808 of FIG. 8. For example, in one embodiment, the processor 304 can control the host vehicle 1806 according to the acceleration control rate by providing automatic braking and/or acceleration for speed control based on the acceleration control rate. In some embodiments, the processor 304 can control the vehicle interface system 328 to provide merge assist feedback to the driver of the host vehicle 1806. In other embodiments, an active force pedal (AFP) of the acceleration pedal 514 can be controlled to provide active feedback force to the driver's foot as the driver pushes the acceleration pedal 514. The method 1900 will now be described in more detail with reference to FIGS. 20 and 21.

In one embodiment, merge assistance is provided to the host vehicle by providing speed guidance. The speed guidance assists the host vehicle 1806 to a proper speed for merging relative to the remote vehicles 1808. FIG. 20 illustrates a method 2000 for speed guidance using the vehicle communication network 200. At block 2002, the method 2000 includes activating a merge assist system similar to block 1902 of FIG. 19. At block 2004, the method 2000 includes receiving V2V remote vehicle data 604 via the vehicle communication network 200. More specifically, the processor 304 can receive speed data transmitted from the one or more remote vehicles 1808 travelling in a merge lane (i.e., the lane 1804 a) via the vehicle communication network 200. For example, the processor 304 can receive speed data transmitted from the one or more remote vehicles 1808 via the vehicle communication network 200.

At block 2006, the method 2000 can include accessing host vehicle data from the host vehicle. For example, as discussed above with block 804 of FIG. 8, host vehicle data 602 can be accessed from the vehicle sensor system 322 of the host vehicle 1806 via the bus 330. In one embodiment, the processor 304 accesses and/or retrieves a speed of the host vehicle 1806 and a position of the host vehicle 1806.

At block 2008, the method 2000 includes calculating an average speed of the one or more remote vehicles 1808 that are in the merge lane (i.e., the lane 1804 a). The processor 304 can calculate the average speed based on the speed data received from each of the remote vehicles 1808 via the vehicle communication network 200 at block 2004. Additionally, the processor 304 can compare the average speed to the speed of the host vehicle 1806 at block 2010. Based on the comparison, at block 2012, the method 2000 can include calculating an acceleration control rate based on the average speed and/or the comparison between the average speed to the host vehicle 1806. The acceleration control rate can be calculated by the processor 304 to minimize a difference between the average speed of the one or more remote vehicles 1808 and the speed of the host vehicle 1806.

Said differently, the average speed can be used to calculate and/or set a target acceleration rate of the host vehicle 1806. The processor 304 can determine whether the speed of the host vehicle 1806 is above or below the target acceleration rate. For example, if the processor 304 determines the speed of the host vehicle 1806 is less than the target acceleration rate, the processor 304 at block 2014 can control a vehicle system of the host vehicle 1806 to inform the driver and/or automatically control the host vehicle 1806 to increase acceleration, as discuss herein. For example, the processor 304 can send a command based on the comparison to the AFP of the acceleration pedal 514 thereby providing a soft feedback that encourages the driver to provide more acceleration in order to merge into the lane 1804 a. Alternatively or in addition, the processor 304 can provide a visual indication to increase acceleration to the vehicle interface system 328. Further, in some embodiments, at block 2014, the processor 304 can output the acceleration control rate to the vehicle system to control motion of the host vehicle 1806 according to the acceleration control rate.

If the processor 304 determines that the speed of the host vehicle 1806 is greater than the target speed of the host vehicle 1806, the processor 304 at block 2014 can send commands to control the AFP of the acceleration pedal 514 to provide active force feedback that simulates a pushing force (e.g., pushing back or against) to the foot of the driver. The active force feedback that simulates the pushing force can be provided with a feedback force that correlates to a difference between the speed of the host vehicle 1806 and the target speed of the host vehicle 1806. Thus, the driver of the host vehicle 1806 is encouraged to accelerate and/or decelerate the host vehicle 1806 with a force that correlates to the difference between the speed of the host vehicle 1806 and the target speed of the host vehicle 1806. Further, the processor 304 can provide a visual indication to decrease and/or increase speed to the vehicle interface system 328. The brightness of the visual indication can be synchronized with the AFP feedback force that is positively correlated to the difference in speed.

In addition to providing speed guidance as discussed above with FIG. 20, the systems and methods discussed herein can determine accurate positioning for merge assistance. Referring now to FIG. 21, a method 2100 for merge assistance using position guidance according to an exemplary embodiment is shown. At block 2102, the method 2100 includes activating a merge assist system similar to block 1902 of FIG. 19. At block 2104, the method 2100 includes receiving remote vehicle data. In one embodiment, the processor 304 can receive V2V remote vehicle data 604 (e.g., speed data) as discussed above at block 2004 of FIG. 20. Further, in this embodiment, the processor 304 can receive sensed remote vehicle data 606. More specifically, the processor 304 can receive position data about one or more of the remote vehicles 1808 via the plurality of midrange sensors (e.g., sensed remote vehicle data from the radar system 414). Additionally, the method 2100 at block 2106 can include accessing host vehicle data 602 as discussed above with block 804 of FIG. 8.

At block 2108, it is determined if any objects (e.g., remote vehicles 1808, hazards) are detected based on the sensed remote vehicle data 606. More specifically, the processor 304 determines if one or more remote vehicles 1808 are in an area around the host vehicle 1806 based on the position data. If the determination at block 2108 is NO, the method 2100 can proceed to block 2114 to control the vehicle system 404 of the host vehicle 1806 based on the position data. For example, FIG. 22A illustrates a traffic scenario 2202 which is a simplified illustration of the traffic scenario 1800 including the host vehicle 1806. In this example, no radar objects (e.g., remote vehicles, hazards) are detected in the merge lane 1804 a. Accordingly, the processor 304 can control the vehicle interface system 328 to provide a visual indication that it is safe to merge the host vehicle 1806 into the merge lane 1804 a. For example, the vehicle interface system 328 can provide a green light on the display 510. In other embodiments, the processor 304 may control one or more vehicle systems 404 to assist the driver and/or the host vehicle 1806 to merge in to the merge lane 1804 a.

Referring again to FIG. 21, if the determination at block 2108 is YES, the method 2100 can optionally proceed to block 2110 to identify a type of merge scenario based on a relative position of the host vehicle 1806 to the one or more remote vehicles 1808. In one embodiment, the vehicle computer system 302 stores merge model data 318. The merge model data 318 can be used to identify the type of merge scenario. Thus, control of the vehicle systems 404 implemented at block 2114 can be based, in part, on the type of merge scenario. Additionally, in some embodiments, the remote vehicle classification method described in FIGS. 13, 14A, and 14C can be used to identify and classify the type of merge scenario. In one embodiment, the type of merge scenario is one of: a side by side merge scenario as shown in FIG. 22B, a tail merge scenario as shown in FIG. 22C, a lead merge scenario as shown in FIG. 22D, or an in-between merge scenario as shown in FIGS. 22E and 22F. Each of these scenarios will be discussed in more detail herein.

At block 2112, the method 2100 can optionally include calculating an acceleration control rate and/or calculating a safe distance for merging into the lane based on a relative position of the host vehicle 1206 to the one or more remote vehicles 1808, a speed of the host vehicle 1806, and a speed of the one or more remote vehicles 1808. In some embodiments, the acceleration control rate and/or the safe distance is also calculated based on the type of merge scenario determined at block 2112. It is understood that in some embodiments, calculating the acceleration control rate can be implemented using equations (1)-(5) discussed above.

With reference to FIG. 22B, a side by side merge scenario 2204 is shown. More specifically, at least one of the remote vehicles, namely, the remote vehicle 1808 a is located adjacent to the host vehicle 1806 in the merge lane 1804 a. The remote vehicle 1808 a is detected based on the sensed remote vehicle data 606 received at block 2104. In this example, based on the type of merge scenario, at block 2112, the processor 304 can calculate an acceleration control rate to slow down the host vehicle 1806. The processor 304, at block 2114, can control a braking system based on the acceleration control rate by providing a deceleration rate. In one embodiment, the deceleration rate is 0.08 G. Alternatively and/or in addition to the automatic braking control, the processor 304 can provide a visual indication to the vehicle interface system 328 to alert and/or encourage an increase in acceleration to merge. For example, a visual indication can be provided on the display 510 to advise the driver of the host vehicle 1806 to slow down by providing a red colored lighting indication. The red color lighting indication could also indicate to the driver that it is not acceptable to merge into the merge lane 1804 a. Additionally, the processor 304 can control the AFP by providing a large counter feedback force. In one embodiment, the large counter feedback force may include a 100% counter force.

Referring again to FIG. 21, as mentioned above, at block 2112, the method 2100 can also include determining a safe distance for merging into the merge lane. In one embodiment, the safe distance is a safe boundary for the host vehicle 1806 to merge into the merge lane 1804 a based on one or more remote vehicles 1808 in the merge lane 1804 a. In some embodiments, the safe distance is based on the type of merge scenario identified at block 2110. With reference to FIG. 22C, a tail merge scenario 2206 according to an exemplary embodiment is shown. Here, the host vehicle 1806 is positioned adjacent (e.g., in the adjacent lane) to the remote vehicle 1808 a and at the tail end of the remote vehicle 1808 a. In one embodiment, the processor 304 determines the host vehicle 1806 is positioned to the side (e.g., adjacent) of the remote vehicle 1808 a and at the tail end of the remote vehicle 1808 a and can identify the type of merge scenario as a tail merge scenario based on the merge models 318. Based on the type of merge scenario, at block 2112, the processor 304 calculates an acceleration control rate to slow down the host vehicle 1806.

In another embodiment, the processor 304 determines a safe distance for the host vehicle 1806 to merge into the merge lane 1804 a according to the following equation:

DS=m+1.5s*(V _(HV) −V _(RV))  (10)

where m is a constant variable in meters, V_(HV) is a speed of the host vehicle 1806, and V_(RV) is a speed of the remote vehicle 1808 a. In some embodiments, the safe distance is limited to a predetermined range, that can be based in part on the merge type. For example, for a tail merge scenario, between 4 and 25 meters. In one illustrative example, the constant variable m is 5 m. However, in some embodiments, the safe distance equation (10) shown above can be based on the speed of the host vehicle 1806 and the speed of the remote vehicle 1808 a. For example, if the processor 304 determines the speed of the host vehicle 1806 is greater than the speed of the remote vehicle 1808 a, the constant variable m can be increased (e.g., from 5 m to 10 m) resulting in a larger safe distance. However, if the speed of the host vehicle 1806 is less than the speed of the remote vehicle 1808 a, the constant variable m can be decreased (e.g., from 5 m to 2 m) resulting in a smaller safe distance.

In one embodiment, the processor 304 determines an actual distance D_(X) between the host vehicle 1806 and the remote vehicle 1808 a as shown in FIG. 22C. The processor 304 can compare the actual distance to the safe distance. If the actual distance is less than the safe distance, then the processor 304 determines it is not safe for the host vehicle 1806 to merge into the lane 1804 a because there is a risk of collision between the host vehicle 1806 and the remote vehicle 1808 a. Accordingly, in one embodiment, at block 2114, the processor 304 can control the vehicle interface system 328 to provide feedback to slow down the host vehicle 1806. For example, a visual indication can be provided on the display 510 indicating it is not safe to merge. Otherwise, if the processor 304 determines the actual distance is greater than the safe distance, the processor 304 determines it is safe for the host vehicle 1806 to merge into the lane 1804 a. The processor 304 can control the vehicle interface system 328 to provide feedback that it is safe to merge into the lane 1804 a. For example, the processor 304 can control the display 510 to display a green light indicator.

In another embodiment, calculating the safe distance at block 2112 can also include calculating a control value for controlling a vehicle system. For example, upon determining the actual distance between the host vehicle 1806 and the remote vehicle 1808 a is less than the safe distance, the processor 304 can calculate a control value as a function of a difference between the actual distance and the safe distance. In one embodiment, the control value is calculated according to the following equation:

$\begin{matrix} {{CV} = \frac{D_{X} - \left\lbrack {{5\mspace{14mu} m} + {1.5\mspace{14mu} s*\left( {V_{HV} - V_{RV}} \right)}} \right\rbrack}{5\mspace{14mu} m}} & (11) \end{matrix}$

The control value can be saturated to a predetermined range. In one example, the control value is saturated to a range of −1 to 0. The control value can be used to control one or more of the vehicle systems 404 at block 2114. For example, upon determining the actual distance is less than the safe distance, the processor 304 can calculate an acceleration control rate, based in part on the control value. As another example, the processor 304 can control the display 510 to provide a red colored light with a brightness that can be modified and/or adjusted based on the control value. For example, the brightness of the red colored light can increase as the control value increases. Thus, the closer the host vehicle 1806 is to the remote vehicle 1808 a, the higher the control value and/or the stronger the feedback. In another embodiment, the AFP counter force (e.g., feedback force) can be adjusted and/or modified based on the control value. The AFP feedback force can increase as the control value increases.

Referring now to FIG. 22D, a lead merge scenario 2208 is shown according an exemplary embodiment. Here, the host vehicle 1806 is positioned to the side (e.g., in the adjacent lane) of the remote vehicle 1808 a and at the front end of the remote vehicle 1808 a. In one embodiment, the processor 304 determines the host vehicle 1806 is positioned to the side of the remote vehicle 1808 a and at the front end of the remote vehicle 1808 a, and can identify the type of merge scenario as a lead merge scenario based on the merge model 318. In some embodiments, the processor 304 can calculate an acceleration control rate to speed up the host vehicle 1806 based on the type of merge scenario.

In another embodiment, the processor 304 determines a safe distance for the host vehicle 1806 to merge into the merge lane 1804 a according to the following equation:

DS=m+1.5s*(V _(HV) −V _(RV))  (12)

where m is a constant variable in meters, V_(HV) is a speed of the host vehicle 1806 and V_(RV) is a speed of the remote vehicle 1808 a. In some embodiments, the safe distance is limited to a predetermined range. For example, between 5 and 12 meters. In one illustrative example, the constant variable m is 8 m. However, in some embodiments, the safe distance equation shown above can be based on the speed of the host vehicle 1806 and the speed of the remote vehicle 1808 a. For example, if the processor 304 determines the speed of the host vehicle 1806 is greater than the speed of the remote vehicle 1808 a, the constant variable m can be increased (e.g., from 8 m to 12 m) resulting in a larger safe distance. However, if the speed of the host vehicle 1806 is less than the speed of the remote vehicle 1808 a, the constant variable m can be decreased (e.g., from 8 m to 4 m) resulting in a smaller safe distance.

In one embodiment, the processor 304 determines an actual distance D_(x) between the host vehicle 1806 and the remote vehicle 1808 a as shown in FIG. 22D. The processor 304 can compare the actual distance to the safe distance. If the actual distance is less than the safe distance, then the processor 304 determines it is not safe for the host vehicle 1806 to merge into the lane 1804 a because there is a risk of collision between the host vehicle 1806 and the remote vehicle 1808 a. Accordingly, in one embodiment, at block 2014, the processor 304 can control the vehicle interface system 328 to provide feedback to increase the speed of the host vehicle 1806. For example, a visual indication can be provided on the display 510 indicating it is not safe to merge. Otherwise, if the processor 304 determines the actual distance is greater than the safe distance, the processor 304 determines it is safe for the host vehicle 1806 to merge into the lane 1804 a. In this scenario, the processor 304 can control the vehicle interface system 328 to provide feedback that it is safe to merge into the lane 1804 a. For example, the processor 304 can control the display 510 to display a green light indicator.

In another embodiment, calculating the safe distance at block 2112 can also include calculating a control value for controlling the vehicle system. For example, upon determining the actual distance between the host vehicle 1806 and the remote vehicle 1808 a is less than the safe distance, the processor 304 can calculate a control value as a function of a difference between the actual distance and the safe distance. In one embodiment, the control value is calculated according to the following equation:

$\begin{matrix} {{CV} = \frac{D_{X} - \left\lbrack {{8\mspace{14mu} m} + {1.5\mspace{14mu} s*\left( {V_{HV} - V_{RV}} \right)}} \right\rbrack}{{8\mspace{14mu} m} + {1.5\mspace{14mu} s*\left( {V_{HV} - V_{RV}} \right)}}} & (13) \end{matrix}$

The control value can be saturated according to a predetermined range. For example, in one embodiment, the control value is saturated to a range of −1 to 0. The control value can be used to control one or more vehicle systems 404 at block 2114. For example, upon determining the actual distance is less than the safe distance, the processor 304 can calculate an acceleration control rate, based in part on the control value. As another example, the processor 304 can control the display 510 to provide a blue colored light with a brightness that can be modified and/or adjusted based on the control value. For example, the brightness of the blue colored light can increase as the control value increases. Thus, the closer the host vehicle 1806 is to the remote vehicle 1808 a, the higher the control value and the stronger the feedback.

With reference to FIGS. 22E and 22F, an in-between merge scenario 2210 and 2212 according to an exemplary embodiment is shown. In FIG. 22E, the host vehicle 1806 is positioned adjacent (e.g., in the adjacent lane) to the remote vehicles 1808 a and 1808 b and in-between the remote vehicles 1808 a and 1808 b. In this embodiment, at block 2112, the processor 304 calculates a safe distance based on a front safe distance from the host vehicle 1806 to the remote vehicle 1808 a and a rear safe distance from the host vehicle 1806 to the remote vehicle 1808 b. More specifically, the front safe distance is calculated according to the following equations:

Front_(DS) =m+1.5s*(V _(HV) −V _(RVF))  (14)

where m is a constant variable in meters, V_(HV) is a speed of the host vehicle 1806 and V_(RVF) is a speed of the front remote vehicle 1808 a. In some embodiments, the safe distance is limited to a predetermined range, that can be based in part, on the merge type. For example, for an in-between scenario as shown in FIG. 22E, the safe distance can be limited between 4 and 20 meters. In one embodiment, the processor 304 determines an actual front distance D_(FX) between the host vehicle 1806 and the front remote vehicle 1808 a. The processor 304 can compare the actual front distance to the front safe distance. If the actual front distance is less than the safe front distance, then the processor 304 determines it is not safe for the host vehicle 1806 to merge into the lane 1804 a because there is a risk of collision between the host vehicle 1806 and the front remote vehicle 1808 a. Accordingly, in one embodiment, at block 2114, the processor 304 can control the vehicle interface system 328 to provide feedback to slow down the host vehicle 1806. For example, a visual indication can be provided on the display 510 indicating it is not safe to merge.

In another embodiment, calculating the safe distance at block 2112 can also include calculating a control value for controlling the vehicle system. For example, upon determining the actual front distance between the host vehicle 1806 and the front remote vehicle 1808 a is less than the safe front distance, the processor 304 can calculate a control value as a function of a difference between the actual front distance and the safe front distance. In one embodiment, the control value is calculated according to the following equation:

$\begin{matrix} {{Front}_{CV} = \frac{D_{FX} - \left\lbrack {{5\mspace{14mu} m} + {1.5\mspace{14mu} s*\left( {V_{HV} - V_{RVF}} \right)}} \right\rbrack}{5\mspace{14mu} m}} & (15) \end{matrix}$

The control value can be saturated to a predetermined range. In one example, the control value is saturated to a range of −1 to 0. The control value can be used to control one or more vehicle systems 404 at block 2114. For example, upon determining the actual front distance is less than the safe distance, the processor 304 can calculate an acceleration control rate, based in part on the control value. As another example, the processor 304 can control the display 510 to provide a red colored light with a brightness that can be modified and/or adjusted based on the control value. For example, the brightness of the red colored light can increase as the control value increases. Thus, the closer the host vehicle 1806 is to the front remote vehicle 1808 a, the higher the control value and the stronger the feedback. In another embodiment, the AFP counter force (e.g., feedback force) can be adjusted and/or modified based on the control value. The AFP feedback force can increase as the control value increases.

With reference to in-between merge scenario 2212 of FIG. 22F, the host vehicle 1806 is closer to the rear remote vehicle 1808 b than the front remote vehicle 1808 a. This is in contrast to the in-between merge scenario 2210 of FIG. 22E where the host vehicle 1806 was closer to the front remote vehicle 1808 a than the rear remote vehicle 1808 b. In the embodiment of FIG. 22F, at block 2112, the processor 304 calculates a safe distance based on a rear safe distance from the host vehicle 1806 to the rear vehicle 1808 b. More specifically, the rear safe distance is calculated according to the following equations:

Rear_(DS) =m+1.5s*(V _(HV) −V _(RVR))  (16)

where m is a constant variable in meters, V_(HV) is a speed of the host vehicle 1806 and V_(RVR) is a speed of the rear remote vehicle 1808 b. In some embodiments, the safe distance is limited to a predetermined range, that can be based in part, on the merge type. For example, for an in-between scenario as shown in FIG. 22F, the safe distance can be limited between 5 and 8 meters. In one embodiment, the processor 304 determines an actual rear distance D_(RX) between the host vehicle 1806 and the rear remote vehicle 1808 b as shown in FIG. 22F. The processor 304 can compare the actual rear distance to the rear safe distance. If the actual rear distance is less than the safe rear distance, then the processor 304 determines it is not safe for the host vehicle 1806 to merge into the lane 1804 a because there is a risk of collision between the host vehicle 1806 and the rear remote vehicle 1808 b. Accordingly, in one embodiment, at block 2114, the processor 304 can control the vehicle interface system 328 to provide feedback to increase the speed of the host vehicle 1806. For example, a visual indication can be provided on the display 510 indicating it is not safe to merge.

In another embodiment, calculating the safe distance at block 2112 can also include calculating a rear control value for controlling the vehicle system. For example, upon determining the actual rear distance between the host vehicle 1806 and the rear remote vehicle 1808 a is less than the rear safe distance, the processor 304 can calculate a control value as a function of a difference between the actual rear distance and the safe rear distance. In one embodiment, the control value is calculated according to the following equation:

$\begin{matrix} {{Rear}_{CV} = \frac{D_{X} - \left\lbrack {{8\mspace{14mu} m} + {1.5\mspace{14mu} s*\left( {V_{HV} - V_{RV}} \right)}} \right\rbrack}{{8\mspace{14mu} m} + {1.5\mspace{14mu} s*\left( {V_{HV} - V_{RV}} \right)}}} & (17) \end{matrix}$

The control value can be saturated to a predetermined range. In one example, the control value is saturated to a range of −1 to 0. The control value can be used to control one or more vehicle systems 404 at block 2114. For example, upon determining the actual rear distance is less than the rear safe distance, the processor 304 can calculate an acceleration control rate, based in part on the control value. As another example, the processor 304 can control the display 510 to provide a blue colored light with a brightness that can be modified and/or adjusted based on the control value. For example, the brightness of the blue colored light can increase as the control value increases. Thus, the closer the host vehicle 1806 is to the rear remote vehicle 1808 b, the higher the control value and the stronger the feedback.

Based on the equations above, if the processor 304 determines that the actual rear distance is greater than the rear safe distance and the actual front distance is greater than the front safe distance, the processor 304 determines that it is safe for the host vehicle 1806 to merge into the lane 1804 a. The processor 304 can control the vehicle interface system 328 to provide feedback that it is safe to merge into the lane 1804 a. For example, the processor 304 can control the display 510 to display a green light indicator.

The embodiments discussed herein can also be described and implemented in the context of computer-readable storage medium storing computer executable instructions. Computer-readable storage media includes computer storage media and communication media. For example, flash memory drives, digital versatile discs (DVDs), compact discs (CDs), floppy disks, and tape cassettes. Computer-readable storage media can include volatile and nonvolatile, removable and non-removable media implemented in any method or technology for storage of information such as computer readable instructions, data structures, modules or other data. Computer-readable storage media excludes non-transitory tangible media and propagated data signals.

It will be appreciated that various implementations of the above-disclosed and other features and functions, or alternatives or varieties thereof, can be desirably combined into many other different systems or applications. Also that various presently unforeseen or unanticipated alternatives, modifications, variations or improvements therein can be subsequently made by those skilled in the art which are also intended to be encompassed herein. 

1. A computer-implemented method for controlling a vehicle system of a host vehicle merging into a lane with one or more remote vehicles, comprising: determining an actual distance between the host vehicle and the one or more remote vehicles, wherein the actual distance is a longitudinal distance between the host vehicle and the one or more remote vehicles; determining a safe distance for merging into the lane based on a relative position of the host vehicle to the one or more remote vehicles, a speed of the host vehicle, and a speed of the one or more remote vehicles, wherein the safe distance is a second longitudinal distance between the host vehicle and the one or more remote vehicles; and controlling the vehicle system of the host vehicle to assist a merge maneuver by the host vehicle according to the actual distance and the safe distance.
 2. The computer implemented method of claim 1, including identifying a type of merge scenario based on the relative position of the host vehicle to the one or more remote vehicles.
 3. The computer-implemented method of claim 2, wherein determining the safe distance is based on the type of merge scenario.
 4. The computer-implemented method of claim 1, including determining a control value as a function of a difference between the actual distance and the safe distance, wherein controlling the vehicle system of the host vehicle includes controlling the vehicle system of the host vehicle based on the control value.
 5. The computer-implemented method of claim 1, wherein controlling the vehicle system of the host vehicle to assist the merge maneuver includes controlling the vehicle system of the host vehicle to assist the merge maneuver upon determining the actual distance is less than the safe distance.
 6. The computer-implemented method of claim 1, including receiving speed data transmitted from the one or more remote vehicles via a vehicular communication network.
 7. The computer-implemented method of claim 1, including receiving position data of the one or more remote vehicles from a sensor system of the host vehicle that monitors an area around the host vehicle.
 8. The computer-implemented method of claim 1, including determining an intent to merge into the lane based on host vehicle data received from a sensory system of the host vehicle.
 9. A vehicle control system for controlling a vehicle system of a host vehicle merging into a lane with one or more remote vehicles, comprising: a wireless transceiver to receive message packets transmitted from the one or more remote vehicles via one or more communication links using a vehicular communication network, wherein each message packet contains speed data of the one or more remote vehicles from which the message packet is transmitted; and a processor operatively connected for computer communication to the wireless transceiver, wherein the processor: determines an actual distance between the host vehicle and the one or more remote vehicles, wherein the actual distance is a longitudinal distance between the host vehicle and the one or more remote vehicles; calculates a safe distance for merging into the lane based on a relative position of the host vehicle to the one or more remote vehicles, a speed of the host vehicle, and a speed of the one or more remote vehicles, wherein the safe distance is a second longitudinal distance between the host vehicle and the one or more remote vehicles; and controls the vehicle system of the host vehicle motion of the host vehicle according to the actual distance and the safe distance.
 10. The vehicle system of claim 9, wherein the processor identifies a type of merge scenario based on the relative position of the host vehicle to the one or more remote vehicles.
 11. The vehicle system of claim 10, wherein calculating the safe distance is based on the type of merge scenario.
 12. The vehicle system of claim 10, wherein the type of merge scenario includes at least one of: a side-by-side merge scenario, a tail end merge scenario, a lead merge scenario, and an in-between merge scenario.
 13. The vehicle system of claim 9, wherein the processor calculates a control value as a function of a difference between the actual distance and the safe distance, wherein controlling the vehicle system of the host vehicle includes controlling the vehicle system of the host vehicle based on the control value.
 14. The vehicle system of claim 9, wherein the processor controls the vehicle system of the host vehicle motion of the host vehicle according to the actual distance and the safe distance upon determining the actual distance is less than the safe distance.
 15. The vehicle system of claim 9, including a sensor system to receive position data of the one or more remote vehicles where the sensor system monitors an area around the host vehicle.
 16. A non-transitory computer-readable storage medium including instructions that when executed by a processor, cause the processor to: determine an actual distance between a host vehicle and one or more remote vehicles, wherein the actual distance is a longitudinal distance between the host vehicle and the one or more remote vehicles; determine a safe distance for merging into a lane based on a relative position of the host vehicle to the one or more remote vehicles, a speed of the host vehicle, and a speed of the one or more remote vehicles, wherein the safe distance is a second longitudinal distance between the host vehicle and the one or more remote vehicles; and control the vehicle system of the host vehicle to assist a merge maneuver by the host vehicle according to the actual distance and the safe distance.
 17. The non-transitory computer-readable storage medium of claim 16, including causing the processor to identify a type of merge scenario based on the relative position of the host vehicle to the one or more remote vehicles.
 18. The non-transitory computer-readable storage medium of claim 17, wherein the processor calculates the safe distance based on the type of merge scenario.
 19. The non-transitory computer-readable storage medium of claim 16, including causing the processor determine a control value as a function of a difference between the actual distance and the safe distance, wherein the processor controls the vehicle system of the host vehicle includes based on the control value.
 20. The non-transitory computer-readable storage medium of claim 16, wherein the processor controls the vehicle system of the host vehicle to assist the merge maneuver upon the processor determining the actual distance is less than the safe distance. 